Pursuant to 35 U.S.C. § 371, this application is a United States National Stage Application of PCT Patent Application Serial No. PCT/US2019/016836, filed on Feb. 6, 2019, the contents of which are incorporated by reference as if set forth in their entirety herein.
A printing system, as one example of a fluid ejection system, may include a printhead, an ink supply which supplies liquid ink to the printhead, and an electronic controller which controls the printhead. The printhead ejects drops of print fluid through a plurality of nozzles or orifices onto a print medium. Suitable print fluids may include inks and agents for two-dimensional or three-dimensional printing. The printheads may include thermal or piezo printheads that are fabricated on integrated circuit wafers or dies. Drive electronics and control features are first fabricated, then the columns of heater resistors are added and finally the structural layers, for example, formed from photo-imageable epoxy, are added, and processed to form microfluidic ejectors, or drop generators. In some examples, the microfluidic ejectors are arranged in at least one column or array such that properly sequenced ejection of ink from the orifices causes characters or other images to be printed upon the print medium as the printhead and the print medium are moved relative to each other.
Certain examples are described in the following detailed description and in reference to the drawings, in which:
Printheads are formed using die having fluidic actuators, such as microfluidic ejectors and microfluidic pumps. The fluidic actuators can be based on thermal or piezoelectric technologies, and are formed using long, narrow pieces of silicon, termed dies herein. As used herein, a fluidic actuator is a device on a die that forces a fluid from a chamber and includes the chamber and associated structures. In examples described herein, one type of fluidic actuator, a microfluidic ejector, is used as a drop ejector, or nozzle in a die used for printing and other applications. For example, printheads can be used as fluid ejection devices in two-dimensional and three-dimensional printing applications and other high precision fluid dispensing systems including pharmaceutical, laboratory, medical, life science and forensic applications.
The cost of printheads is often determined by the amount of silicon used in the dies, as the cost of the die and the fabrication process increase with the total amount of silicon used in a die. Accordingly, lower cost printheads may be formed by moving functionality off the die to other integrated circuits, allowing for smaller dies.
Many current dies have an ink feed slot in the middle of the die to bring ink to the fluidic actuators. The ink feed slot generally provides a barrier to carrying signals from one side of an die to another side of a die, which often requires duplicating circuitry on each side of the die, further increasing the size of the die. In this arrangement, fluidic actuators on one side of the slot, which may be termed left or west, have independent addressing and power bus circuits from fluidic actuators on the opposite side of the ink feed slot, which may be termed right or east.
Examples described herein provide a new approach to providing fluid to the fluidic actuators of the drop ejectors. In this approach, the ink feed slot is replaced with an array of fluid feed holes disposed along the die, proximate to the fluidic actuators. The array of fluid feed holes disposed along the die may be termed a feed zone, herein. As a result, signals can be routed through the feed zone, between the fluid feed holes, for example, from the logic circuitry located on one side of the fluid feed holes to printing power circuits, such as field-effect transistors (FETs), located on the opposite side of the fluid feed holes. This is termed cross-slot routing herein. The circuitry to route the signals includes traces that are provided in layers between adjacent ink or fluid feed holes.
As used herein, a first side of the die and a second side of the die denote the long edges of the die that are in alignment with the fluid feed holes, which are placed near or at the center of the die. Further, as used herein, the fluidic actuators are located on a front face of the die, and the ink or fluid is fed to the fluid feed holes from a slot on the back face of the die. Accordingly, the width of the die is measured from the edge of the first side of the die to the edge of the second side of the die. Similarly, the thickness of the die is measured from the front face of the die to the back face of the die.
The cross-slot routing allows for the elimination of duplicate circuitry on the die, which can decrease the width of the die, for example, by 150 micrometers (μm) or more. In some examples, this may provide a die with a width of about 450 μm or about 360 μm, or less. In some examples, the elimination of duplicate circuitry by the cross-slot routing may be used to increase the size of the circuitry on the die, for example, to enhance performance in higher value applications. In these examples, the power FETs, the circuit traces, power traces, and the like, may be increased in size. This may provide dies that are capable of higher droplet weights. Accordingly, in some examples, the dies may be less than about 500 μm, or less than about 750 μm, or less than about 1000 μm.
The thickness of the die from the front face to the back face is also decreased by the efficiencies gained from the use of the fluid feed holes. Previous dies that use ink feed slots may be greater than about 675 μm, while dies using the fluid feed holes may be less than about 400 μm in thickness. The length of the dies may be about 10 millimeters (mm), about 20 mm, or about 20 mm, depending on the number of fluidic actuators used for the design. The length of the dies includes space at each end of the die for circuitry, accordingly the fluidic actuators occupy a portion of the length of the die. For example, for a black die of about 20 mm in length, the fluidic actuators may occupy about 13 mm, which is the swath length. A swath length is the width of the band of printing, or fluid ejection, formed as a printhead is moved across a print medium.
Further, it allows the co-location of similar devices for increased efficiency and layout. The cross-slot routing also optimizes power delivery by allowing left and right columns, or fluidic actuator zones, of multiple fluidic actuators to share power and ground routing circuits. A narrower die may be more fragile than a wider die. Accordingly, the die may be mounted in a polymeric potting compound that has a slot from a reverse side to allow ink to flow to the fluid feed holes. In some examples, the potting compound is an epoxy, although it may be an acrylic, a polycarbonate, a polyphenylene sulfide, and the like.
The cross-slot routing also allows for the optimization of circuit layout. For example, the high-voltage and low-voltage domains may be isolated on opposite sides of the fluid feed holes allowing for improvements in reliability and form factor for the dies. The separation of the high-voltage and low-voltage domains may decrease or eliminate parasitic voltages, crosstalk, and other issues that affect the reliability of the die. Further, repeat units that include the logic circuits, fluidic actuators, fluid feed holes, and power circuitry for a set of nozzles may be designed to provide the desired pitch in a very narrow form factor.
The fluid feed holes placed in a line parallel to a longitudinal axis of the die may make the die more susceptible to damage from mechanical stresses. For example, the fluid feed holes may act as a series of perforations that increase the chance that a crack will develop through the fluid feed holes along the longitudinal axis of the die. To detect cracks during manufacturing, for example, before mounting in the potting compound, a crack detection circuit may be placed around the fluid feed holes in a serpentine manner. The crack detection circuit may be a resistor that breaks if a crack forms, causing the resistance to go from a first resistance, such as hundreds of kiloohms, to an open circuit. This may lower production costs by identifying broken dies prior to completion of the manufacturing process.
The die used for a printhead, as described herein, uses resistors to heat fluids in the fluidic actuator causing droplet ejection by thermal expansion. However, the dies are not limited to thermally driven fluidic actuators and may use piezoelectric fluidic actuators that are fed from fluid feed holes. As described herein, the fluidic actuator includes the driver and associated structures, such as the fluid chamber and a nozzle for a microfluidic ejector.
Further, the die may be used in to form fluidic actuators for other applications besides a printhead, such as microfluidic pumps, used in analytical instrumentation. In this example, the fluidic actuators may be fed test solutions, or other fluids, rather than ink, from fluid feed holes. Accordingly, in various examples, the fluid feed holes and inks can be used to provide fluidic materials that may be ejected or pumped by droplet ejection from thermal expansion or piezoelectric activation.
In contrast to the fluid feed slot 104 of the die 100, the die 200 uses fluid feed holes 204 to provide fluid, such as inks, to the fluidic actuators 206 for ejection by thermal resistors 208. As described herein, the cross-slot routing allows circuitry to be routed along silicon bridges 210 between the fluid feed holes 204 and across the longitudinal axis 212 of the die 200. This allows the width 214 of the die 200 to be substantially decreased over previous designs that did not have the fluid feed holes 204.
The decrease in the width 214 of the die 200 decreases costs substantially, for example, by decreasing the amount of silicon in the substrate of the die 200. Further, the distribution of circuitry and functions between the die and the ASIC 202 allows further decreases in the width 214. As described herein, the die 200 also includes sensor circuitry for operations and diagnostics. In some examples, the die 200 includes thermal sensors 216, for example, placed along the longitudinal axis of the die near one end of the die, at the middle of the die, and near the opposite end of the die.
On top of the FOX layer 808, the polysilicon layers 508 are deposited, for example, to couple logic circuitry on one side of the die 200 to power transistors on an opposite side of the die 200. Other uses for the polysilicon layers 508 may include crack detection traces deposited between fluid feed holes 204, as described with respect to
A layer of metal 1 516 may then be deposited over the first dielectric layer 812. In various examples, metal 1 516 is formed from titanium nitride (TiN), aluminum copper alloy (AlCu), or titanium nitride/titanium (TiN/Ti), among other materials, such as gold. A second dielectric layer 814 is deposited over the metal 1 516 layer to provide an insulation barrier. In an example, the second dielectric layer 814 is a TEOS/TEOS layer formed by a high-density plasma chemical vapor deposition (HDP-TEOS/TEOS).
A layer of metal 2 518 may then be deposited over the second dielectric layer 814. In various examples, metal 2 518 is formed from a tungsten silicon nitride alloy (WSiN), aluminum copper alloy (AlCu), or titanium nitride/titanium (TiN/Ti), among other materials, such as gold. A passivation layer 816 is then deposited over the top of metal 2 518 to provide an insulation barrier. In an example, the passivation layer 816 is a layer of silicon carbide/silicon nitride (SiC/SiN).
A tantalum (Ta) layer 818 is deposited over the top of the passivation layer 816 and the second dielectric layer 814. The tantalum layer 818 protects the components of the trace from degradation caused by potential exposure to fluids, such as inks. A layer of SU-8 820 is then deposited over the die 200, and is etched to form the nozzles 320 and flow channels 822 over the die 200. SU-8 is an epoxy based negative photoresist, in which parts exposed to a UV light are cross-linked, becoming resistant to solvent and plasma etching. Other materials may be used in addition to, or in place of, the SU-8. The flow channels 822 are configured to feed fluid from the fluid feed holes, or fluid feed holes 204, to the nozzles 320 or fluidic actuators. In each of the flow channels 822, a button 824 or protrusion is formed in the SU-8 820 to block particulates in the fluid from entering the ejection chambers under the nozzles 320. One button 826 is shown in the cross section of
The stacking of conductors over the silicon layer 806 between the fluid feed holes 204 increases the connections between left and right sides of the array of fluid feed holes 204. As described herein, the polysilicon layer 508, metal 1 layer 516, metal 2 layer 518, and the like, are all unique conductive layers separated by dielectric, or insulating layers, 812, 814, and 816, that allow them to be stacked. Depending on the design implementation, such as the color die 304 shown in
In an example, a layer of photoresist polymer, such as SU-8, is formed over a portion of the die to protect areas that are not to be etched. The photoresist may be a negative photoresist, which is cross-linked by light, or a positive photoresist, which is made more soluble by light exposure. In an example, a mask is exposed to a UV light source to fix portions of the protective layer, and portions not exposed to UV light are washed away. In this example, the mask prevents cross-linking of the portions of the protective layer covering the area of the fluid feed holes.
At block 904, a plurality of layers is formed on the substrate to form the die. The layers may include the polysilicon, the dielectric over the polysilicon, metal 1, the dielectric over metal 1, metal 2, the passivation layer over metal 2, and the tantalum layer over the top. As described above, the SU-8 may then be layered over the top of the die, and patterned to implement the flow channels and nozzles. The formation of the layers may be formed by chemical vapor deposition to deposit the layers followed by etching to remove portions that are not needed. The fabrication techniques may be the standard fabrication used in forming complementary metal-oxide-semiconductors (CMOS). The layers that can be formed in block 904 and the location of the components is discussed further with respect to
As described herein, the use of the fluid feed holes allow circuitry to cross the die in traces formed over silicon between the fluid feed holes. Accordingly, circuits may be shared between each side of the die, decreasing the total amount of circuits needed on the die.
At block 1110, ejector power circuits are formed along a second side of the die. In some examples, the ejector power circuits include field-effect transistors (FETs) and thermal inkjet (TIJ) resistors used to heat a fluid to force the fluid to be ejected from a nozzle. At block 1112, power circuit power lines are formed along the second side of the die. The power circuit power lines are high-voltage power lines (Vpp) and return lines (Pgnd) used to supply power to the ejector power circuits, for example, at a voltage of about 25 to about 35 V.
At block 1114, traces coupling the logic circuits to power circuits, between the fluid feed holes, are formed. As described herein, the traces may carry signals from logic circuits located on the first side of the die to power circuits on the second side of the die. Further, traces may be included to perform crack detection between the fluid feed holes, as described herein.
In dies in which the nozzle circuitry is separated by a center fluid feed slot, logic circuitry, address lines, and the like are repeated on each side of the center fluid feed slot. In contrast, in dies formed using the methods of
In each primitive, NE, NW, SE, and SW, eight addresses, labeled 0 to 7, are used to select a nozzle for firing. In other examples, there are 16 addresses per primitive, and 64 nozzles per quad primitive. The addresses are shared, wherein an address selects a nozzle in each group. In this example, if address four is provided, then nozzles 1204, activated by FETs F9, F10, F25, and F26 are selected for firing. Which, if any, of these nozzles 1204 fire depends on separate primitive selections, which are unique to each primitive. A fire signal is also conveyed to each primitive. A nozzle within a primitive is fired when address data conveyed to that primitive selects a nozzle for firing, data loaded into that primitive indicates firing should occur for that primitive, and a firing signal is sent.
In some examples, a packet of nozzle data, referred to herein as a fire pulse group (FPG), includes start bits used to identify the start of an FPG, address bits used to select a nozzle 1202 in each primitive data, fire data for each primitive, data used to configure operational settings, and FPG stop bits used to identify the end of an FPG. Once an FPG has been loaded, a fire signal is sent to all primitive groups which will fire all addressed nozzles. For example, to fire all the nozzles on the printhead, an FPG is sent for each address value, along with an activation of all the primitives in the printhead. Thus, eight FPG's will be issued each associated with a unique address 0-7. The addressing shown in the schematic diagram 1200 may be modified to address concerns of fluidic crosstalk, image quality, and power delivery constraints. The FPG may also be used to write to a non-volatile memory element associated with each nozzle, for example, instead of firing the nozzle.
A central fluid feed region 1206 may include fluid feed holes or a fluid feed slot. However, if the central ink feed region 1206 is a fluid feed slot, the logic circuitry and addressing lines, such as the three address lines in this example that are used provide addresses 0-7 for selecting a nozzle to fire each primitive, are duplicated, as traces cannot cross the central ink feed region 1206. If, however, the central fluid feed region 1206 is made up of fluid feed holes, each side can share circuitry, simplifying the logic.
Although the nozzles 1202 in the primitives described in
In this example, logic circuitry 1308 for primitives on both the east and west side of the die share access to the digital power bus 1302, digital signal bus 1304, and the sense bus 1306. Further, the address decoding may be performed in a single logic circuit for a group of primitives 1310, such as the primitives NW and NE. As a result, the total circuitry required for the die is decreased.
An address logic zone includes address line circuits, such as primitive logic circuitry 1504 and decode circuitry 1506. The primitive logic circuitry 1504 couples the address lines to the decode circuitry 1506 for selecting a nozzle in a primitive group. The primitive logic circuitry 1504 also stores data bits loaded into the primitive over the data lines. The data bits include the address values for the address lines, and a bit associated with each primitive that selects whether that primitive fires an addressed nozzle or saves data.
The decode circuitry 1506 selects a nozzle for firing or selects a memory element in a memory zone that includes non-volatile memory elements 1508, to receive the data. When a fire signal is received over the data lines in the bus 1502, the data is either stored to a memory element in the non-volatile memory elements 1508 or used to activate an FET 1510 or 1512 in a power circuitry zone on the power circuitry 512 of the color die 304. Activation of an FET 1510 or 1512 provides power to a corresponding TIJ resistor 1516 or 1518 from a shared power (Vpp) bus 1514. In this example, the traces include power circuitry to power TIJ resistors 1516 or 1518. Another shared power bus 1520 may be used to provide a ground for the FETs 1510 and 1512. In some examples, the Vpp bus 1514 and the second shared power bus 1520 may be reversed.
A fluid feed zone includes the fluid feed holes 204 and the traces between the fluid feed holes 204. For the color die 304, two droplet sizes may be used, which are each ejected by thermal resistors associated with each nozzle. A high weight droplet (HWD) may be ejected using a larger TIJ resistor 1516. A low weight droplet (LWD) may be ejected using a smaller TIJ resistor 1518. Electrically, the HWD nozzles are in the first column, for example, west, as described with respect to
The efficiency of the layout may be further improved by changing the size of the corresponding FETs 1510 and 1512 to match the power demand of the TIJ resistors 1516 and 1518. Accordingly, in this example, the size of the corresponding FETs 1510 and 1512 are based on the TIJ resistor 1516 or 1518 being powered. A larger TIJ resistor 1516 is activated by a larger FET 1512, while a smaller TIJ resistor 1518 is activated by a smaller FET 1510. In other examples, the FETs 1510 and 1512 are the same size, although the power drawn through the FETs 1510 used to power smaller TIJ resistors 1518 is lower.
A similar circuit floorplan may be used for a black die 302. However, as described for examples herein, the FETs for a black die are the same size, as the TIJ resistors and nozzles are the same size.
The black die 302 is wider than the color die 304, since nozzles 320 are on both sides of the fluid feed holes 204. In some examples, the black die 302 is about 400 to about 450 μm. In some examples, the color die 304 is about 300 to about 350 μm.
The trace 2004 between the fluid feed holes 204 may be made from a brittle material. While metal traces may be used, the ductility of the metal may allow it to flex across cracks that have formed without detecting them. Accordingly, in some examples the trace 2004 between fluid feed holes 204 are made from polysilicon. If the trace between the fluid feed holes 204 throughout the black die 302, both alongside and between the fluid feed holes 204, were made from polysilicon, the resistance may be as high as several megaohms. In some examples, to reduce the overall resistance and improve the detectability of cracks, the portions 2006 of the trace 2004 formed alongside the fluid feed holes 204 and connecting the traces 2004 between the fluid feed holes 204 are made from a metal, such as aluminum-copper, among others.
At block 2204, a number of layers are formed on the substrate to form the crack detector trace, wherein the crack detector trace is routed between each of the plurality of fluid feed holes on the substrate. As described herein, the layers are formed to loop from side to side of the die, between each pair of adjacent fluid feed holes, along the outside of a next fluid feed hole, and then between the next pair of adjacent fluid feed holes. In examples, layers are formed to couple the crack detector trace to a sense bus that is shared by other sensors on the die, such as the thermal sensors described with respect to
The present examples may be susceptible to various modifications and alternative forms and have been shown only for illustrative purposes. Furthermore, it is to be understood that the present techniques are not intended to be limited to the particular examples disclosed herein. Indeed, the scope of the appended claims is deemed to include all alternatives, modifications, and equivalents that are apparent to persons skilled in the art to which the disclosed subject matter pertains.
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PCT/US2019/016836 | 2/6/2019 | WO |
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WO2020/162924 | 8/13/2020 | WO | A |
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