An inkjet-printing device, such as an inkjet printer, is a type of fluid-ejection that forms an image on media like paper by ejecting ink onto the media. Examples of images include text, graphics, photos, and a combination thereof. In some situations, image quality is enhanced when the ink deposited onto the media is uniform in thickness and is optically flat. Optical flatness ensures that light incident to the image is reflected clearly without scattering.
As noted in the background section, the quality of images formed on media like paper by ejecting ink onto the media is enhanced when the ink deposited onto the media is uniform in thickness and is optically flat. However, the thickness uniformity and the optical flatness of the ink can be non-optimal. To improve these characteristics of the ink as the ink dries on the media, different techniques can be employed.
First, the ink may be heated while the ink is drying, which has been found to improve the thickness uniformity and the optical flatness of the ink. However, adding a heater to an inkjet-printing device can add unwanted cost and bulk to the device. Second, the ink may be formulated to include various surfactants that decrease ink-drying time, which has also been found to improve the thickness uniformity and the optical flatness of the ink.
However, such surfactants can be undesirable. They may decrease the usable life and reliability of the printhead or other fluid-ejection mechanism of the inkjet-printing device. The surfactants may be incompatible with the pigments of some types of inks that give the inks their color. Some surfactants are environmentally unsound in their use, disposal, and/or manufacture, and their use may be regulated or even prohibited.
Disclosed herein is an electrowetting platen for use in a fluid-ejection device that can overcome these disadvantages. A fluid-ejection mechanism can eject fluid, such as ink, onto a swath of media, like paper or a polymeric printing substrate, positioned against this platen. The platen can generate an electric field to affect the fluid that is ejected onto the media. For instance, the fluid ejected onto the media can be affected by the electric field such that its thickness uniformity and optical flatness are improved. The fluid ejected onto a given swath of media can be affected both while the swath is positioned against the platen (i.e., while the swath is currently receiving fluid from the fluid-ejection mechanism), as well as after the media has been advanced so that the swath is no longer positioned against the platen.
The fluid-ejection mechanism 102 can be a printhead, such as inkjet printhead, and ejects fluid like ink, which may be an electrically conductive ink or an electrically non-conductive ink. The fluid-ejection mechanism 102 ejects fluid drops 116 onto a current portion of media 118, which may be paper, that is positioned against the electrowetting platen 104. This portion of the media 118 is referred to as a swath of the media 118.
In one example operation of the fluid-ejection device 100, the media 118 is moved in the direction indicated by the arrow 120 in
In another example operation of the fluid-ejection device 100, the width of the fluid-ejection mechanism 102 along the y-axis 112 may span the media 118 between the edges of the media 118 along the y-axis 112. In this example, the fluid-ejection mechanism 102 can be stationary, instead of having to be moved as indicated by the arrows 122 in
The electrowetting platen 104 generates an electric field as the fluid-ejection mechanism 102 ejects fluid onto a swath of the media 118, to affect the fluid that is deposited onto this swath. The power source 106 provides direct current or alternating current to the electrowetting platen 104 so that the platen 104 generates a constant electric field or a varying electric field, respectively.
The controller 108, which may be implemented in software, hardware, or a combination thereof, controls the power source 106 to apply the current to the electrowetting platen 104. The controller 108 also may control movement of and ejection of fluid by the fluid-ejection mechanism 102.
The electrowetting platen 104 is a platen in that it is the component of the fluid-ejection device 100 against which a swath of the media 118 is positioned for the fluid-ejection mechanism 102 to eject fluid onto the swath. The electrowetting platen 104 is electrowetting in that it generates the electric field that affects the fluid deposited on the swath of the media 118. Electrowetting can be generally defined as the modification of the wetting behavior of a fluid on a hydrophobic surface with an applied electric field. It is noted that the electric field generated by the electrowetting platen 104 can affect the fluid deposited on the media 118 even after the current swath of media 118 has been advanced along the x-axis 110 is thus is no longer positioned against the platen 104.
The fluid-ejection device 100 is more generally a fluid-application device that applies fluid to the media 118. As such, the fluid-ejection mechanism 102 is more generally a fluid-application mechanism that applies fluid to the media 118. Examples of fluid-application devices and mechanisms include such devices and components that rely upon ejection to apply fluid to the media, such as via thermal ejection and piezoelectric ejection. Other examples include devices and components that coat the media with fluid, that roll fluid onto the media, that cause the media to be dipped into fluid, and so on.
The swath of the media 118 is positioned against at least the substrate 202 while the fluid-ejection mechanism 102 ejects fluid onto a swath of the media 118. The electrodes 204, which more generally are an electrowetting mechanism, generate an electric field 206 while the fluid-ejection mechanism 102 is ejecting fluid onto the swath. The electric field 206 affects the fluid ejected onto the swath.
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The fluid ejected onto the swath can be affected by the electric field 206 generated by the electrowetting platen 104 in a number of different ways. As has been noted, the thickness and optical flatness of the fluid as the fluid dries on the swath of the media 118 can be improved (306). In general, this can be achieved by the controller 108 applying a direct current to the electrodes 204 of the electrowetting platen 104 via the power source 106. As such, the electrodes 204 generate a constant electric field.
The fluid ejected onto the swath can be affected by the electric field 206 generated by the electrowetting platen 104 in other ways as well, generally by the controller 108 appropriately applying an alternating current to the electrodes 204 via the power source 106 so that the electrodes 204 generate a suitable varying electric field to achieve a desired effect. The resolution of the image formed by the fluid ejected onto the media 118 can be effectively increased by moving the drops 116 of the fluid that have been ejected onto the swath (308). Similarly, any errors in placement of the drops 116 can be corrected to at least some extent by moving the drops 116 that have been ejected onto the swath (310).
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In general, then, the electrowetting achieved by the electrowetting platen 104 provides for quality improvements of the fluid ejected onto the media 118, as well as for other effects. Quality is improved, for instance, by improving thickness uniformity and optical flatness, per part 306 of
The effects that have been described in relation to parts 308, 310, 312, 314, 316, and 318 in particular can be achieved by applying different types of electric fields. For instance, electric fields that have different characteristics may result from using an alternating current as opposed to a direct current. As such, the electric fields may be varied appropriately to affect the placement of fluid drops as has been described in relation to these parts of the method 300 of
As noted above, the fluid-ejection device 100 that has been described may be an inkjet-printing device, which is a device, such as a printer, that ejects ink onto media, such as paper, to form images, which can include text, on the media. The fluid-ejection device 100 is more generally a fluid-ejection, precision-dispensing device that precisely dispenses fluid, such as ink, melted wax, or polymers. The fluid-ejection device 100 may eject pigment-based ink, dye-based ink, another type of ink, or another type of fluid. Examples of other types of fluid include those having water-based or aqueous solvents, as well as those having non-water-based or non-aqueous solvents. However, any type of fluid-ejection, precision-dispensing device that dispenses a substantially liquid fluid may be used.
A fluid-ejection precision-dispensing device is therefore a drop-on-demand device in which printing, or dispensing, of the substantially liquid fluid in question is achieved by precisely printing or dispensing in accurately specified locations, with or without making a particular image on that which is being printed or dispensed on. The fluid-ejection precision-dispensing device precisely prints or dispenses a substantially liquid fluid in that the latter is not substantially or primarily composed of gases such as air. Examples of such substantially liquid fluids include inks in the case of inkjet-printing devices. Other examples of substantially liquid fluids thus include drugs, cellular products, organisms, fuel, and so on, which are not substantially or primarily composed of gases such as air and other types of gases, as can be appreciated by those of ordinary skill within the art.
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JPO computer-generated English language translation of Hanada et al. JP 2010-0247407 A downloaded Mar. 21, 2013; patent published Nov. 4, 2010. |
Number | Date | Country | |
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20120273352 A1 | Nov 2012 | US |