In the printing industry, ink is often sold in prepackaged containers that are advertised or labeled with a target number of pages that can be printed with the ink. Achieving accurate page yields using the ink in the container fulfills user expectations, allows for accurate scheduling for replacement ink cartridges, and maintains print quality. Ideally, the amount of ink in the container would be just enough to print the target number of pages. However, variations in printheads, print settings, page content and other factors can cause the target number of pages to be missed. There may be too little ink to reach the target number of pages or excess ink remaining in the container after the target number of pages has been met.
The accompanying drawings illustrate various examples of the principles described herein and are a part of the specification. The illustrated examples are merely examples and do not limit the scope of the claims.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
As discussed above, ink containers can be labeled with a target number of pages that can be printed with the ink in the container. The accuracy of the page yield produced using the ink can influence user expectations, print quality, life cycle management and waste generated during the printing process. However, variations in printheads, print settings, page content and other factors can cause the page target to be missed.
One factor which can improve the accuracy of the page yield is an accurate understanding of how much ink is in the container throughout the printing process. Accurate measurements of the ink remaining in the container can allow print settings to be adjusted during printing to meet the page target. However, making accurate measurements of ink remaining in the container can be challenging. For example, ink may be contained in a foam filled container. As ink is dispensed onto the substrate, more ink wicks out of the foam to the printhead. Using foam to contain ink has a number of advantages, but directly measuring the amount of ink remaining in the foam is difficult. Directly measuring the amount of ink remaining in other types of ink containers, such as spring bags and integrated printhead pens can be similarly difficult.
As a result of the difficulty in making accurate measurements of the ink levels, ink containers are often designed to contain more ink than is typically necessary to meet a page target. The ink containers and ink amounts are determined using statistical measures to account for manufacturing and usage variations. For example, a large population of printheads is tested to determine how much ink is consumed by each printhead. The amount of ink in the container is then selected so that the vast majority of the printers will meet the page target. However, this results in larger ink containers, wasted ink, and uncertainty in the actual number of pages that can be printed using the ink containers.
The present specification describes systems and methods for accurately estimating ink remaining in ink containers and adjusting the print settings so that the target number of printed pages is generated without leaving large amounts of ink remaining in the ink container.
In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present systems and methods. It will be apparent, however, to one skilled in the art that the present apparatus, systems and methods may be practiced without these specific details. Reference in the specification to “an example” or similar language means that a particular feature, structure, or characteristic described in connection with the example is included in at least that one example, but not necessarily in other examples.
There are various methods of detecting low-on-ink or out-of-ink events within the inkjet printhead (62). One method uses a weight sensitive switch that is activated when the weight of the ink in the printhead (62) reaches a certain threshold. Another method counts the number of drops (70) that have been ejected from the ink printhead (62) and sends a signal when that number has reached a certain threshold. As discussed above, current end-of-life detection methods are based on statistical averages of a large integrated printhead population. Integrated printhead end-of-life detection can consequently be inaccurate for individual printheads within the population, causing waste and negative user perception.
The inventor has discovered that the change in backpressure in the ink container as a result of dispensing ink can be used to accurately detect ink levels. The change in backpressure influences ink behavior within the droplet generators. Modified droplet generators can then be used to detect the backpressure and ink level.
As shown in
Because of the small size of the droplet generator (100), capillary force/surface tension is a predominant force affecting the interaction of the ink with its surroundings. The capillary action occurs when the external intermolecular forces between the liquid and the solid walls are stronger than the cohesive intermolecular forces inside the liquid. The capillary forces tend to draw the fluid into the firing chamber (110) and hold it there. Ink in the firing chamber (110) and ink reservoir (105) are kept at a lower pressure than the outside air pressure. This backpressure pulls the ink meniscus up into the nozzle (115) in a concave shape, with the edges of the meniscus adhering to the nozzle walls and the center of the meniscus being drawn farther into the nozzle (115). This retains the ink within the nozzle (115) until firing.
In a number of printer designs, the backpressure increases as the ink level in the ink container decreases.
In this example, when the ink container is full of ink, the backpressure is −2 inches of water. As the ink level decreases during printing, the backpressure continues to rise. The increase in backpressure occurs slowly at first, and then increases more rapidly as the ink is almost gone. In this implementation when the ink is depleted the backpressure is −7 inches of water. As used in the specification and appended claims, the term “smaller backpressure” refers to negative backpressures with small absolute values and the term “greater backpressure” refers to negative backpressures with higher absolute values. For example, −2 inches of water is a smaller backpressure than −7 inches of water.
The relationship between backpressure and the amount of ink in the ink reservoir is present in a wide variety of printing systems including integrated printhead systems, off-axis ink supplies, systems that use spring bag ink delivery systems, foam filled ink reservoirs, and other systems. For example, in a foam filled ink reservoir, capillary action draws the ink out of the foam and into the printhead. As the amount of ink in the foam decreases, higher negative pressures at the printhead are needed to draw the ink out of the foam.
After characterization of a printing system, the backpressure can be used to accurately measure the remaining amount of ink in the reservoir. This technique can be particularly useful where accurate direct measurements of the amount of ink in the reservoir are difficult.
Backpressure measurements can be made by using specially designed droplet generators as sensors. These droplet generators are designed to deprime at specific backpressures. As discussed above, the backpressure is a relative measurement of the difference between the ambient air pressure and the internal pressure of fluid in the ink cartridge. The meniscus responds to the backpressure. For example, the backpressure needed to pull the meniscus through a circular orifice (such as the nozzle opening) can be estimated using the following equation.
P=(2σ cos(θ−α))/r (Eq. 1)
Where:
P=backpressure
σ=ink surface tension
θ=ink contact angle
α=nozzle taper angle
r=nozzle radius
As can be seen from the equation above, the pressure needed to pull a meniscus through a circular opening decreases as the radius of the opening increases. It is easier for the meniscus to pass through a large opening than a small opening. When the backpressure exceeds a limit for the nozzle as defined above, the meniscus can detach from the nozzle and travel back through the firing chamber. This empties the firing chamber by allowing outside air to be sucked into the chamber. When the firing chamber is not full of ink, it is “deprimed” and cannot operate until it is again filled with ink. If the firing resistor is activated when the firing chamber is deprimed, the firing resistor has a greater likelihood of being thermally damaged. This is because the fluid which normally carries away heat generated by the firing resistor is absent.
If the meniscus does not encounter an opening smaller than the nozzle from which it just detached, it will continue through the firing chamber and become an expanding bubble in the ink reservoir. However, if the meniscus encounters a smaller opening than the nozzle, it will adhere to that opening until a higher backpressure is reached.
A series of droplet generators with progressively larger nozzle openings will sequentially deprime as the backpressure increases.
As the backpressure within the ink reservoir becomes greater, the fourth droplet generator (340) will be the first to deprime because it has the largest nozzle opening (342). As the backpressure continues to increase, the second and third droplet generators (320, 330) would sequentially deprime. However, the meniscus does not travel all the way into the ink reservoir but is trapped by the passageway constrictions (328, 338, 348). The passageway constrictions (328, 338, 348) can be designed so that the meniscus will not pass the constriction (328, 338, 348) through the complete range of anticipated backpressures. This prevents air from being sucked into the ink reservoir through the firing chamber sensors.
The second droplet generator (320) is used as a backpressure sensor and includes two resistors (321, 324) and a constriction (328) in the passageway (326). In this example, the smaller resistor (324) is a sensing resistor that is designed to fail open when the firing chamber (327) becomes deprimed. This creates a predictable change in the resistance of the firing resistor circuit which can be detected to sense depriming of the firing chamber (327).
The firing resistor (321) may or may not actually cause the ejection of a droplet out of the nozzle. The sensing of the backpressure will typically not occur during actual printing of a substrate. Instead, the backpressure sensing will be timed to occur during calibration or maintenance procedures. Any ink ejected by the droplet generators (320, 330, 340) can be contained and discarded to prevent undesirable print artifacts on the substrate.
Although the resistances R1 and R2 are shown being connected parallel, they could also be connected in other ways, such as individually, in series, or as part of a bridge circuit. In one example, the firing resistor (321) and the sensing resistor (324) have approximately equal resistances. In other examples, the resistors could have different resistances.
Now referring to
In
A similar current is also passed through the resistors (321, 324) in the second droplet generator (320). Throughout this process, the meniscus (415) in the second droplet generator (320) remains in place in the smaller nozzle (315). Because the second droplet generator (320) has not been deprimed at this amount of backpressure, the electrical current does not blow out the sensing resistor (324) in the second droplet generator (320) and the resistances of the resistors (321, 324) remain substantially unchanged.
The sensing circuitry (350,
In
By using the backpressure data points generated by the second and third droplet generators (320, 330), the system can determine the current ink levels within the ink reservoir. The system can then modify printing parameters as needed to successfully reach the target number of printed pages.
Although only two droplet generators which sense backpressure are illustrated in
Droplet generators that act as backpressure sensors are not limited to the designs shown above or designs which are similar to the droplet generators. The droplet generators that act as backpressure sensors could have a variety of geometries, materials and operating characteristics. For example, a droplet generator could have a series of progressively smaller apertures through which the meniscus would pass as the backpressure increased. In another example, the sensor resistor could be constructed from a different material than the firing resistor.
A number of alternative techniques could be used to sense depriming. For example, the capacitance of a firing resistor may change when the droplet generator is deprimed. This change in capacitance could be used to sense depriming. Alternatively, the cooling profile of a firing resistor could be used to determine if the sensor has deprimed. The firing resistor would cool more slowly when the firing chamber is deprimed. In other examples, the electrical resistance/capacitance/inductance between two resistors in the same firing chamber could be sensed. If ink was present firing chamber, the measured electrical characteristic would have a first value or range of values. If ink was absent, the measured electrical characteristic could have a second value or range of values.
In one alternative embodiment, backpressure sensors are constructed from droplet generators which have different nozzle sizes but are otherwise identical to the array of droplet generators which produce images on the substrate. The depriming of specific sensors in response to a given backpressure could be detected by droplet detection sensors already present in the printing system. For example, the droplet generators that do not eject a droplet when the firing resistor is actuated could be identified as deprimed. To reduce the possibility of identifying droplet generators as deprimed which have failed for other reasons, several droplet generators with identical nozzle apertures could be used. When the majority of identical droplet generators in a group fail to eject droplets, the designed backpressure point can be assumed to have been reached. This decreases the likelihood that failure by any one sensor will cause a false backpressure reading. The principle of using redundant sensors can be used in any of the designs described herein.
Additionally, sensor failure can be identified if sensors designed to trigger at backpressures do not correlate. For example, if a high backpressure sensor designed to respond at −7 inches of water is triggered before sensors which are designed to respond at −3 and −4 inches of water are triggered, it can be assumed that the high backpressure sensor has failed.
According to one example, a print cartridge is initially loaded with slightly less ink that would be needed to print the target number of pages at a nominal “pages per million drops” setting. Until trigger A occurs, the printing proceeds with printing pages at the nominal “pages per million drops” setting. These pages are represented by the area of the first box (500). After trigger A occurs, the “pages per million drops” setting of the printer is increased. This results in fewer drops being deposited on each page and more pages being printed for each million drops. Thus, as the “pages per million drops” setting is increased more pages being printed with less ink consumed. However, this change in “pages per million drops” setting is not visually perceptible to the user. This sequence continues as each backpressure trigger occurs. At each step, the total number of pages remaining to be printed and the ink level are determined. A calculation is made or a table lookup is performed to determine how to adjust the “pages per million drops” setting to best meet the target number of printed pages. For example, if the printer is set to use 30 million drops per page before trigger A, after trigger A is detected it can be set to use 29 million drops per page.
In the example shown in
Although the description above uses thermal inkjet printing mechanisms and processes to describe principles for sensing ink backpressure and meeting print targets, the principles can also be applied to other systems, such as piezo-electric driven printheads.
A subset of the droplet generators are used as backpressure sensors (610). As discussed above, these backpressure sensors (610) have nozzle apertures with cross sectional areas which are greater than the cross sectional area of the droplet generators (608) which produce the printed images. Among the backpressure sensors (610), the nozzle apertures can vary in size. Consequently, the backpressure sensors (610) will deprime through a range of backpressures and will deprime at backpressures which are lower than the backpressure at which the droplet generators (608) deprime. Although the nozzle apertures are illustrated and described above as being circular, they may have a variety of geometries.
The passageways between the backpressure sensors (610) and the ink reservoir (602) are restricted such that the minimum cross sectional area in the passageways is smaller than the cross sectional areas of the nozzles of the backpressure sensors (610). Further, the minimum cross-sectional area of the passageways can be smaller than the cross sectional area of the nozzles of the droplet generators (608).
As discussed above, the backpressure sensors (610) may use a variety of methods to sense depriming caused by backpressure in the ink reservoir (602). In one example, each of backpressure sensors (610) include both a firing resistor and sensing resistor. When a sensing resistor is activated in a deprimed firing chamber, the sensing resistor is designed to overheat and fail. The backpressure sensors (610) are electrically connected to sensing circuitry (614). The sensing circuitry (614) includes a resistance measurement component that measures the resistance of the sensing resistor. If the sensing resistor has maintained its original resistance, it can be determined that that particular backpressure sensor (610) is not deprimed and the backpressure at which that particular backpressure sensor (610) deprimes at has not been reached. However, if the resistance measurement component determines that the resistance sensing resistor has increased greater than a predetermined threshold, it is assumed that the backpressure at which the backpressure sensor (610) has deprimes has been reached.
The sensing resistor may not fail during the first electrical pulse that is sent through it after the firing chamber deprimes. A series of electrical pulses over a period of time may be applied to the sensor resistor to cause its resistance characteristics to permanently change. Typically this change will be a measureable increase in resistance, but in some embodiments it may alternatively be a decrease in resistance.
In the implementation shown in
The system shown in
The sensed backpressure can then be correlated to an amount of ink in the ink reservoir (block 710). For example, the depriming a specific backpressure sensor or group of backpressure sensors is determined. The depriming of these backpressure sensors corresponds to a specific backpressure or range of backpressures. This backpressure is related to the amount of ink in the ink reservoir by a predetermined relationship.
The number of pages remaining to meet a predetermined target number of printed pages is determined (block 715) and print settings are adjusted so that the printer can print the pages remaining with the amount of ink in the ink reservoir (block 720). For example, a setting such as “pages printed per million droplets” can be adjusted to increase the number of pages printed per unit of ink.
The method described above is only one illustrative example. Blocks described above may be combined, eliminated, added or modified. For example, the method may include filling the ink reservoir with less ink than will be used to print a predetermined target number of printed pages at a first printer setting. Alternatively, the method may include filling the ink reservoir with more ink than would be required to meet a predetermined target number of printed pages. In this scenario, the amount of ink deposited per printed page could actually increase as the number of printed pages approached the target number.
In conclusion, the systems and methods described above for achieving accurate page yields have a number of advantages. Because the target number of printed pages is consistently obtained, the user can be confident in budgeting for and purchasing replacement cartridges. In some examples, no extra ink needs to be included in the ink container design to ensure that every printer meets the target number of printed pages. Consequently, the container can be smaller, or for ink containers of the original size, the target number of printed pages can be increased.
The preceding description has been presented only to illustrate and describe examples of the principles described. This description is not intended to be exhaustive or to limit these principles to any precise form disclosed. Many modifications and variations are possible in light of the above teaching.
Number | Name | Date | Kind |
---|---|---|---|
4746935 | Allen | May 1988 | A |
5793393 | Coven | Aug 1998 | A |
6398329 | Boyd et al. | Jun 2002 | B1 |
6843545 | Lapstun et al. | Jan 2005 | B2 |
6863364 | Russell et al. | Mar 2005 | B2 |
7744181 | Lapstun et al. | Jun 2010 | B2 |
7747180 | Wittenauer et al. | Jun 2010 | B2 |
20080131146 | Kendall | Jun 2008 | A1 |
20090128596 | Babu | May 2009 | A1 |
Number | Date | Country | |
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20130033546 A1 | Feb 2013 | US |