Printing devices contain a number of printheads used to dispense ink or another jettable fluid onto a print medium. The printheads include a number of dies that are precision dispensing devices that precisely dispense the jettable fluid to form an image on the print medium. The jettable fluid may be delivered via a fluid slot defined in the print head to an ejection chamber beneath a nozzle. Fluid may be ejected from the ejection chamber by, for example, heating a resistive element. The ejection chamber and resistive element form the thermal fluid ejection device of a thermal inkjet (TIJ) printhead. The printing devices may, however, use any type of digital, high precision liquid dispensing system, such as, for example, two-dimensional printing systems, three-dimensional printing systems, digital titration systems, and piezoelectric printing systems, among other types of printing devices.
The accompanying drawings illustrate various examples of the principles described herein and are a part of the specification. The illustrated examples are given merely for illustration, and do not limit the scope of the claims.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
As described above, a thermal inkjet (TIJ) printhead includes a number of TIJ dies. Each TIJ die includes a number of slivers. A die sliver includes a thin silicon, glass or other substrate having a thickness on the order of approximately 650 μm or less. The TIJ slivers may each include a number of fluid ejection devices such as the above-mentioned resistive heating elements on a surface of the slivers. Jettable fluid may flow to the ejection devices of the slivers through a number of fluid slots formed in the substrate between opposing substrate surfaces.
While thermal inkjet (TIJ) devices are described throughout the examples herein, any type of digital, high precision liquid dispensing system may utilize these examples. For example, the printhead may include any two-dimensional (2D) printing elements or devices, any three-dimensional (3D) printing elements or devices, digital titration elements or devices, either thermos-resistor type or piezoelectric type printing elements or devices, other types of digital, high precision liquid dispensing system, or combinations thereof. These various types of liquid dispensing systems may dispense a myriad of types of liquids including, for example, inks, 3D printing agents, pharmaceuticals, lab fluids, and bio-fluids, among other dispensable liquids. The 3D printing agents may include, for example, polymers, metals, adhesives, 3D inks, among others
While fluid slots within a printhead die effectively deliver fluid to the fluid ejection elements, the fluid slots occupy valuable silicon real estate and add significant processing cost in their fabrication. Lower printhead die costs may be achieved in part through shrinking the die size. However, a smaller die size results in a tighter slot pitch and/or a narrower slot width in the silicon substrate, which adds excessive assembly costs associated with integrating the smaller die into the TIJ printhead. Further, removing material from the substrate to form an ink delivery slot structurally weakens the printhead die. Thus, when a single printhead die has multiple slots to improve print quality and speed in a single color printhead die, or to provide different colors in a multicolor printhead die, the printhead die becomes increasingly fragile with the addition of each slot. Thus, one constraint within a TIJ printhead is that higher TIJ die separation ratios or lower die costs are proportional to tighter slot pitch or fluid slot width. From a cost point of view, a fluid slot may occupy useful die space and may have significant processing cost.
Stating it in another way, reducing the cost of inkjet printhead dies may include shrinking the die size and reducing wafer costs. The die size may depend on the pitch of fluid delivery slots formed through the silicon substrate that deliver jettable fluid from a reservoir on one side of the die to fluid ejection elements of the slivers on another side of the die. Therefore, some methods to shrink the die size may involve reducing the slot pitch and size through a silicon slotting process that may include, for example, laser machining, anisotropic wet etching, dry etching, other material removal methods, or combinations thereof. However, the silicon slotting process adds considerable manufacturing costs to the printhead die. Further, as die sizes have decreased, the costs and complexities associated with integrating the smaller dies into an inkjet printhead have begun to exceed the savings gained from the smaller dies. Furthermore, as die sizes have decreased, the removal of die material to form ink delivery slots has had an increasingly adverse impact on die strength, which can increase die failure rates.
In one example, an overmold of epoxy mold compound (EMC) may be used to hold multiple TIJ slivers of a printhead die in place. The inexpensive molded substrate formed by the EMC also provides physical support for interconnect traces, supports wire bonding, and enables TAB bonding in various examples. Overmolded printhead die have three times a reduction in cost. Further, the overmolded printhead die simplify the printhead assembly process since chiclets or other fluid distribution manifolds or fluidic interposers are no longer needed within the printhead. To further reduce the cost, electrical interconnects are extended from the slivers to printed circuit boards (PCB) or lead frames. The PCBs or lead frames connect the slivers to the edge of the die so the printhead can be connected to an electrical contact of a printing device directly instead of using expensive tape-automated bonding (TAB) circuits or surface-mounted technology (SMT) connectors. Thus, the overmolded slivers and their respective electrical interconnects greatly simplify the printhead design and assembly process.
Thus, examples described herein provide a thermal inkjet (TIJ) printhead. The TIJ printhead includes a number of inkjet slivers molded into a moldable substrate. The overmolded inkjet slivers form at least one TIJ die. The TIJ printhead also includes a number of wire bonds electrically coupling the inkjet slivers to a side connector. The side connector electrically couples the inkjet slivers to a controller of a printing device.
In one example, the side connector includes a printed circuit board (PCB) side connector. In this example, the PCB side connector may be molded into the moldable substrate.
In another example, the side connector includes a lead frame embedded into the moldable substrate. In this example, the lead frame includes a number of electrical traces from the wire bonds and a number of connection pads coupled to the electrical traces. The connection pads electrically couple the inkjet slivers to the controller of the printing device. The TIJ printhead may further include an encapsulating cover disposed on the wire bonds.
In one example, the side connector is electrically coupled to the inkjet slivers at an edge of each of the inkjet slivers. Further, in one example, the moldable substrate is an epoxy molding compound (EMC). Epoxy molding compound (EMC) is broadly defined herein as any material including at least one epoxide functional group. In one example, the EMC is a self-cross-linking epoxy. In this example, the EMC may be cured through catalytic homopolymerization. In another example, the EMC may be a polyepoxide that uses a co-reactant to cure the polyepoxide. Curing of the EMC in these examples forms a thermosetting polymer with high mechanical properties, and high temperature and chemical resistance.
Examples described herein also provide a thermal inkjet (TIJ) printhead die. The TIJ printhead die includes a moldable substrate, a number of inkjet slivers molded into the moldable substrate, and a number of electrical wire leads connecting the slivers to an edge connector coupled to the moldable substrate. In one example, the edge connector includes a printed circuit board (PCB) embedded within the moldable substrate, a first set of connectors coupled to the PCB to couple the PCB to the inkjet slivers via the wire leads, and a second set of connectors coupled to the PCB to couple the PCB to a printer controller.
The TIJ printhead may further include an encapsulating material disposed on the wire bonds. In addition, the TIJ printhead die may further include a protective film disposed on the encapsulating material to maintain a low profile of the encapsulating material.
Examples described herein also provide a method of manufacturing a thermal inkjet (TIJ) die. The method may include overmolding a number of inkjet slivers into a moldable substrate, the overmolded inkjet slivers forming at least one TIJ die, electrically coupling a first end of a number of wire bonds to the inkjet slivers, and electrically coupling a second end of the wire bonds to a side connector coupled to an edge of the at least one TIJ die. In one example, overmolding the number of inkjet slivers into the moldable substrate includes overmolding a printed circuit board (PCB) with the number of inkjet slivers into the moldable substrate.
In one example, the method may further include encapsulating the wire bonds with an encapsulating material to preclude exposure of the wire bonds to the environment. Further, in one example, the method may include depositing a protective film on the encapsulating material to maintain a low profile of the encapsulating material.
As used in the present specification and in the appended claims, the terms “printhead” or “printhead die” is meant to be understood broadly as the part of an inkjet printer or other inkjet type dispenser that can dispense jettable fluid from a number of nozzle openings. A printhead includes a number of printhead dies, and a printhead die includes a number of die slivers. A printhead and printhead die are not limited to dispensing ink and other printing fluids, but instead may also dispense other fluids for uses other than printing.
Further, as used in the present specification and in the appended claims, the term “sliver” or “die sliver” means any sub-element of a printhead die that ejects jettable fluid. In one example, the slivers may include thin silicon or glass substrate having a thickness of approximately 200 μm and a ratio of length to width (L/W) of at least three. The slivers may also include an epoxy-based negative photoresist material such as SU-8 layered on the silicon or glass substrate that makes up the nozzles of the sliver.
Even still further, as used in the present specification and in the appended claims, the term “a number of” or similar language is meant to be understood broadly as any positive number comprising 1 to infinity; zero not being a number, but the absence of a number.
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 that example is included as described, but may not be included in other examples.
Turning now to the figures,
As mentioned above, a die sliver includes a thin silicon, glass, or other substrate having a thickness of approximately 650 μm or less, and may also have a ratio of length to width (L/W) of at least three. In one example, the number of slivers (102) included within a TIJ printhead die (100) is equivalent to the number of colors the TIJ printhead die (100) ejects. In the example of
As depicted in
Further, each sliver (102) includes at least one ejection chamber beneath each nozzle. The ejection chamber is fluidically coupled to a number of slots defined within the moldable substrate (101) beneath the sliver through which jettable fluid flows to the ejection chambers and out the nozzles during a firing event of the jettable fluid. Thus, molded fluid flow structures, such as the molded inkjet printhead (100), do not include fluid slots formed through the die sliver substrate. Instead, each die sliver (102) is molded into the monolithic moldable substrate (101) that provides fluidic fan-out through fluid channels formed into the moldable substrate (101) at the back surface of the slivers (102). Thus, a molded printhead structure avoids significant costs otherwise associated with die slotting processes and the related assembly of slotted dies into manifold features (e.g., chiclets) of the printhead (100).
Fluid slots formed into the moldable substrate (101) enable jettable fluid to flow to the back surface of each die sliver (102). Fluid/ink feed holes (IFH) formed through the die sliver (102) from its back surface to its front surface enable the fluid to flow through the sliver (102) to the ejection chambers on the front surface such as the ejection chambers including the resistive heating elements described above. The jettable fluid is ejected from the slivers (102) of the molded printhead (100) through nozzles fluidically coupled to the fluid ejection chambers.
In one example, the aspects described herein may be implemented in a printhead bar such as those used in a page-wide array. In this example, a print bar may include a number of molded printhead dies (102) embedded in the moldable substrate (101). Each molded printhead die includes a number of die slivers (102) having a front surface and a back surface exposed outside of the molding. The back surface is to receive fluid and the front surface is to dispense fluid that flows from the back surface to the front surface through fluid feed holes in the die sliver.
In one example, the molded printhead dies (100) may be arranged along a print bar or a page-wide array. In this example, the molded printhead dies (100) may be arranged end to end along the length of a printhead in a number of different configurations. In one example, the molded printhead dies (100) may be arranged in an inline configuration. In another example, the molded printhead dies (100) may be arranged in a staggered configuration where the slivers (102) are aligned with respect to one another but the dies (100) are staggered along the longitudinal axis of print bar. In still another example, the molded printhead dies (100) may be arranged in a rotated configuration where the slivers (102) are aligned with respect to one another but the dies (100) are rotated with respect to a longitudinal axis of the print bar. In yet another example, the molded printhead dies (100) may be arranged in a slanted configuration where the slivers (102) are arranged in a slanted arrangement with respect to one another but the dies (100) are aligned with respect to a longitudinal axis of the print bar. In still another example, the molded printhead dies (100) may be arranged in a stitching configuration where a number of the dies (100) overlap an adjacent a number of the dies. In this example, the overlap of the dies (100) allows for nozzle stitching of those nozzles of the slivers (102) of the die (100). Stitching of the nozzles may be accomplished, in one example, by timing the firing of any overlapping nozzles such that the combined firing of ejection fluid from the overlapped nozzles does not eject any more or less jettable fluid than other non-overlapping nozzles.
In another example, the molded printhead dies (100) may be included within a print cartridge. In this example, a single printhead die (100) may be included in the print cartridge. In the examples described herein, a printed circuit board (PCB) may be embedded or coupled to the edge of the moldable substrate (101). In one example, the PCB is a FR-4 (fire retardant-4) grade PCB. An FR-4 grade PCB denotes a glass-reinforced epoxy laminate sheet. FR-4 PCB is a composite material composed of woven fiberglass cloth with an epoxy resin binder that is flame resistant or self-extinguishing. As mention above, the “FR-4” designation denotes that safety of flammability of FR-4 is in compliance with the standard UL94V-0. In one example, FR-4 may be created from a number of materials including epoxy resin, woven glass fabric reinforcement, brominated flame retardant, or combinations thereof, and is a versatile high-pressure thermoset plastic laminate grade with good strength to weight ratios. With near zero water absorption, an FR-4 grade PCB may be used as an electrical insulator possessing considerable mechanical strength, and retains its high mechanical values and electrical insulating qualities in both dry and humid conditions. Further, an FR-4 grade PCB substrate has good fabrication characteristics. Details regarding an embedded or coupled PCB will be described below.
In one example, the slivers (102) included in the printhead die (100) each include a number of connection pads. However, the slivers (102), as molded within the moldable substrate (101), are unable to electrically couple to a printing device (
The printhead die (100) of
In one example of
In the example of
Further, a protective film (112) may be placed on the encapsulant (111). The protective film (112) causes the encapsulant (111) to be sandwiched between a number of surfaces of the printhead die (100) and the protective film (112). This, in turn, causes the encapsulant (111) and protective film (112) to maintain a low profile so that the encapsulant (111) does not protrude from the surface of the printhead (100) to a degree at which the encapsulant (111) disrupts printing operations.
Again, in order to provide electrical connectivity between the slivers (102) and a controller (
In an example where the wire bonds (105) directly couple the first electrical connections (104) of the connection pad (103) to the fourth electrical connections (110), the wire bonds (105) reach to the fourth electrical connections (110), and the encapsulant (111) is placed over the wire bonds (105) for the entire length of the wire bonds (105). Further, as depicted in
In
Again,
In one example, overmolding (block 1301) the number of inkjet slivers (102) into the moldable substrate (101) includes overmolding a printed circuit board (PCB) (108) with the number of inkjet slivers (102) into the moldable substrate (101). The method may further include encapsulating the wire bonds (102) with an encapsulating material such as the encapsulant (111) to preclude exposure of the wire bonds (102) to the environment. A protective film (112) may be deposited on the encapsulating material (111) to maintain a low profile of the encapsulating material (111).
The specification and figures describe a thermal inkjet (TIJ) printhead. The TIJ printhead includes a number of inkjet slivers molded into a moldable substrate. The overmolded inkjet slivers form at least one TIJ die. The TIJ printhead also includes a number of wire bonds electrically coupling the inkjet slivers to a side connector. The side connector electrically couples the inkjet slivers to a controller of a printing device. This TIJ printhead may (1) eliminate the need to include chiclets or other fluid distribution manifolds or fluidic interposers in the printhead; (2) decrease manufacturing costs and increase cost efficiency through the use of epoxy mold compound (EMC) instead of expensive and difficult to manufacture silicon substrates; (3) reduce the silicon area within the printhead such that a 3 times or greater reduction in die cost is realized; (4) simplify the electrical interconnect to the printing device; and (5) greatly simplify the design of the printhead and the assembly process of the printhead, among other advantages.
The preceding description has been presented 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 | Date | Country | |
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Parent | 15748914 | Jan 2018 | US |
Child | 16595015 | US |