Inkjet printers are commonly used both for large scale printing, such as on banners and other signage items, as well as for small scale general consumer printing. Inkjet printers typically include a number of ink nozzles configured to eject ink onto a print medium such as paper. The process of ejecting a droplet of ink is often referred to as firing. Ink nozzles are typically fired through use of an ejection mechanism. One type of ejection mechanism is a thermal resistor. The thermal resistor heats ink within a small chamber associated with each nozzle. This causes the ink within the chamber to expand, causing an ink droplet to be propelled from the ink nozzle opening onto the print medium.
The accompanying drawings illustrate various embodiments of the principles described herein and are a part of the specification. The illustrated embodiments 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.
Inkjet printing system developers strive to design printing systems capable of printing high quality images at fast speeds. The density of the ink nozzles on the printhead affects the speed and quality of the printing system. Generally, a higher density array of ink nozzles is able to produce a higher quality image. Additionally, the rate at which the ink nozzles fire affects the speed of the printing system. A higher frequency of ink nozzle firings can produce an image in a smaller period of time. In addition, a higher number of ink nozzles can increase print speed. This can be done by using redundant nozzles with alternating firing. For example, one ink nozzle can be refilling its associated small ink chamber while an alternate ink nozzle is firing.
The ink nozzle density of an ink nozzle array is limited by the structure of the materials forming the array. Particularly, the ink nozzle array is limited by the structure of the wafer in which the small ink chambers associated with each ink nozzle is formed. Additionally, the rate at which ink nozzles are able to be fired is limited by the thermal efficiency of the ink chambers and their associated ink nozzles. The rate at which ink nozzles can be fired is also limited by the rate that each chamber refills with ink after the ink has been fired from that ink chamber.
The present specification discloses an ink nozzle array structure that seeks to address these issues. According to certain illustrative examples, the ink nozzle array embodying principles described herein includes a number of ink nozzles formed on a surface of a semiconductor substrate. The semiconductor substrate includes a membrane layer, a stopping layer, and a handle layer. Throughout this specification and in the appended claims, the term “membrane layer” refers to a layer which is used to support circuitry for a number of ink nozzles. The term “stopping layer” refers to a material used to control an etching process. The term “handle layer” refers to a layer used to provide support for a stopping layer and a membrane layer.
An ink supply trench is formed into the handle layer of the substrate. This leaves the membrane layer and the stopping layer to span across the width of the ink supply trench. The semiconductor membrane layer may be made of a standard semiconductor material such as silicon.
A set of ink chambers is placed on a surface of the membrane layer of the substrate above and along a width of the ink supply trench formed into the handle layer of the substrate. Each ink chamber is able to receive ink through ink feedholes formed through the membrane layer to the ink supply trench below. This set of ink chambers defines one dimension of the two-dimensional array. The second dimension of the ink nozzle array is along the length of the ink supply trench. Additional sets of ink chambers spanning the membrane layer are placed along the length of the ink supply trench. For example, four ink chambers may span the width of the ink supply trench. In one possible example, two hundred of these sets of four ink chambers may be placed along the length of the ink supply trench. This creates a 4×200 ink nozzle array.
As will be described below and illustrated in the figures, without the membrane layer, only a one-dimensional array of ink nozzles may be formed across a single ink supply trench. To form a two-dimensional array without the membrane layer, several small ink supply trenches are placed in parallel and in as close proximity as possible. A single line of ink chambers is then formed adjacent to each side of the ink supply trench. With this structure, the nozzle density is only limited by how tightly the ink chambers can be packed next to the ink supply trench.
In addition, the stopping layer between the membrane layer and the handle layer provides a mechanism for accurately controlling the etching process. A finer control over the etching process allows precise shaping of the ink supply trench and ink feedholes. This finer control provides a more durable and thermally efficient ink nozzle array.
Through use of a substrate with a stopping layer as described herein, a two-dimensional array of ink chambers may be placed above and use the same ink supply trench. The semiconductor material making up the membrane layer allows for circuitry to be formed for connecting to and engaging the ejection mechanism associated with each ink chamber. By having two dimensions of ink chambers placed above and sharing the same ink supply trench, a greater ink nozzle density can be achieved. Additionally, more freedom is given to space the ink nozzles in a thermally efficient manner. Furthermore, the fluid path transporting ink from the ink-supply trench to the ink chamber can be minimized for faster refill.
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 embodiment,” “an example” or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment or example is included in at least that one embodiment, but not necessarily in other embodiments. The various instances of the phrase “in one embodiment” or similar phrases in various places in the specification are not necessarily all referring to the same embodiment.
Throughout this specification and in the appended claims, the term “ink” is to be interpreted as any type of fluid which can be ejected from an ink nozzle.
Referring now to the figures,
The control system (108) may include components of a standard physical computing system such as a processor and a memory. The memory may include a set of instructions that cause the processor to perform certain tasks related to the printing of images. For example, the control system (108) may manage the various mechanical components within the print engine (104). Additionally, the control system (108) may convert the image data sent from a client computing system to a format which is used by the print engine (104).
The ink cartridge (110) may be designed to support several printheads. Each printhead may dispense a different color of ink such that full-color images can be produced. As the ink cartridge (110) moves with respect to the print medium (102) and/or the print medium (102) moves underneath the ink cartridge (110), the control system (108) may send a signal to the appropriate inkjet ink nozzle (106) associated with the printheads of the ink cartridge (110) to eject an ink droplet. Ink droplets are ejected in a specific pattern so as to create an intended image on print medium (102).
Ink nozzle arrays can be built onto a silicon substrate (212) such as a silicon wafer. The use of the silicon material (206) allows electronic circuitry to be formed on a surface of the wafer. This circuitry layer (216) is formed with a number of thin films. The thin films can be layers of dielectric materials, conductive materials and semi-conductive materials. This circuitry is used to select and fire the ink nozzles within the array (200).
An ink nozzle can be fired through a variety of methods. One such method is referred to as thermal inkjet printing. Thermal inkjet ink nozzles are fired when the ink inside the chambers (202) is heated. The ink is heated by a thermal resistor (206). The thermal resistor (206) takes electrical energy received via the circuitry layer (216) and transfers that energy into thermal energy. This thermal energy that is absorbed by the ink within the ink chamber (204) causes some of the ink to vaporize. The vapor bubble propels a droplet of ink through the ink nozzle (208) and onto a print medium such as paper.
After an ink droplet has been propelled out of the ink chamber, the collapsing vapor bubble and capillary forces pull in more ink from an ink supply trench (218) to refill the ink chamber (204). A single ink supply trench (218) supplies multiple ink chambers (204), and those ink chambers are placed along the sides of the trench. The arrow illustrates the direction of ink flow (202).
This structure limits the placement of nozzles to single lines on either side of an ink-supply trench. In light of this issue, the present specification discloses use of a substrate which includes a stopping layer between a membrane layer and a handle layer. As mentioned above, the ink supply trench is formed into the handle layer and the ink chambers are formed on a surface of the membrane layer above and across the width of the ink supply trench. The stopping layer provides a mechanism for finer control of the etching process.
The pattern of the ink chambers (302) may be designed in a variety of ways to suit various printing systems. For example, the orientation of the chambers may be altered so that the ink feedholes (304) are on different sides of the ejection mechanism. Additionally, a set (318) of ink chambers may span an ink supply trench (308) at an angle as shown in
Ink nozzles are typically formed onto a semiconductor substrate such as silicon. This substrate is often referred to as a wafer or a die. Use of a semiconductor material for building ink nozzles allows formation of the circuitry which selects and causes ink to be fired from an ink nozzle. Particularly, the semiconductor material is used to form transistor devices which can act as switches or amplifiers used in the circuitry.
The stopping layer (404) is placed between the handle layer (406) and the membrane layer (406). The stopping layer (404) is sometimes referred to as a buried oxide layer. The stopping layer can be made of an oxide material such as silicon dioxide. During the etching process, which will be described in more detail below, the stopping layer (404) is etched away at a slower rate. This allows for the creation of cleaner edges by making it easier to time the etching process.
The membrane layer (406) is also made of a semiconductor material. For example, the membrane layer (406) may be made of silicon. The thickness of the membrane layer may range from 10-50 micrometers (μm). The membrane layer (406) provides semiconductor locations for placing ejection mechanisms and other circuitry elements despite the removal of the semiconductor wafer (402) below.
In the present example, a resistor (408) is used as an ejection mechanism. The resistor (408) receives a firing signal via the circuitry within the thin film circuitry layer (410). As mentioned above, the thin film circuitry layer may include conductive traces which carry electrical signals to the resistors (408). Other types of ejection mechanisms may be used as well. For example, a piezoelectric inkjet system propels ink droplets out of an ink chamber by applying a voltage across a piezoelectric film bordering the ink within the chamber. The piezoelectric film realigns its molecules under an applied voltage. This causes the film, to expand and propel ink out of the nozzle. The piezoelectric film may be placed in a similar position as the resistors of a thermal inkjet ink chamber.
Semiconductor substrates (412) that include a second material disposed between two semiconductor materials are sometimes manufactured in bulk to be used for a variety of other purposes. These types of substrates are often referred to as a silicon-on-insulator substrate. An ink nozzle embodying principles described herein may make use of such prefabricated silicon-on-insulator substrates. For example, a prefabricated silicon-on-insulator substrate may include two semiconductor layers with an insulating layer in between those two layers. The insulating layer can be used as a stopping layer. Additionally, one of the layers can be ground down to the appropriate thickness to form the membrane layer.
The ink feedholes (502) can be formed through various photolithographic and etching processes. Through these processes, a mask is used to determine where etching should occur. This mask can be designed so that the etching occurs at the appropriate locations. The etching process continues until the stopping layer (404) is reached. As mentioned above, the stopping layer (404) etches away at a much slower rate than then the membrane layer (406). This makes it easier to time the etching process so that the ink feedholes (502) are formed at the proper depth.
For purposes of illustration, the process described in the text accompanying
In some cases, ink feedholes (502) can be formed on more than one side of the resistor (408).
In conclusion, through use of the membrane layer described herein, a two-dimensional array of ink chambers may be placed above and use the same ink supply trench. The semiconductor material making up the membrane layer allows for circuitry to be formed for connecting to and engaging the ejection mechanism associated with each ink chamber. By having two dimensions of ink chambers placed above and sharing the same ink supply trench, a greater ink nozzle density can be achieved. Additionally, more freedom is given to space the ink nozzles in a thermally efficient manner.
The preceding description has been presented only to illustrate and describe embodiments and 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.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/US2010/048976 | 9/15/2010 | WO | 00 | 3/6/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2012/036682 | 3/22/2012 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
6394586 | Isshiki | May 2002 | B2 |
6607259 | Mott et al. | Aug 2003 | B2 |
6938340 | Haluzak et al. | Sep 2005 | B2 |
7255425 | Lai et al. | Aug 2007 | B2 |
7566118 | Bibl et al. | Jul 2009 | B2 |
7637593 | Silverbrook et al. | Dec 2009 | B2 |
8141987 | Hayakawa et al. | Mar 2012 | B2 |
20030058309 | Haluzak et al. | Mar 2003 | A1 |
20060192808 | Hoisingyon et al. | Aug 2006 | A1 |
20080295308 | Wijngaards et al. | Dec 2008 | A1 |
Number | Date | Country |
---|---|---|
20080033111 | Apr 2008 | KR |
20090058225 | Jun 2009 | KR |
I295239 | Apr 2008 | TW |
Number | Date | Country | |
---|---|---|---|
20130162717 A1 | Jun 2013 | US |