Printing devices are widely used and may include a printhead die enabling formation of text or images on a print medium. Such a printhead die may be included in an inkjet pen or printbar that includes channels that carry ink. For instance, ink may distributed from an ink supply to the channels through passages in a structure that supports the printhead die(s) on the inkjet pen or printbar.
Printers that utilize a substrate wide printbar assembly have been developed to help increase printing speeds and reduce printing costs. Substrate wide printbar assemblies often tend to include multiple parts that carry printing fluid from the printing fluid supplies to the small printhead dies from which the printing fluid is ejected on to paper or other print substrate. It may be desirable to shrink the size of a printhead die. However, decreasing the size of a printhead die can involve changes to structures that support the printhead die, including passages that distribute ink to the printhead die. While reducing the size and spacing of the printhead dies continues to be associated with reducing cost, channeling printing fluid from supply components to tightly spaced dies may in turn lead to comparatively complex flow structures and fabrication processes that can actually increase an overall cost associated with a printhead die.
Forming such complex flow structures may itself involve use of difficult processes and/or additional materials such as carrier boards having prefabricated openings that extend through the carrier board. A prefabricated opening refers to an opening and/or combination of opening that alone or together extend through the carrier board and that are formed prior to printhead die attachment. Prefabricated openings can, for example, include windows, ink feed slots, etc. that extend through such a carrier board. Carrier boards having prefabricated openings may prove costly, ineffective, and/or difficult (time-consuming) to procure and/or utilize, among other shortcomings. For instance, such prefabricated openings may lead to reduced structure integrity (compared to use of solid carrier boards that are without prefabricated openings) and/or other difficulties, such as undesired migration of an adhesive material into a prefabricated opening.
In contrast, the printbars and methods of forming printbars, as described herein, include a printed circuit board (PCB), adhesive material, a printhead die sliver, and a slot extending through the PCB and the adhesive material (e.g., a portion of the adhesive material) to the printhead die sliver (e.g., to an ink feed hole included in the printhead die sliver). Advantageously, the printbars and methods of forming the printbars of the present disclosure do not include a prefabricated opening in the PCB. Moreover, the PCB can include a dam surrounding a perimeter of a recess included in the PCB. Such a recess and/or a dam can promote adhesive material placement, printhead die positioning (e.g., positioning such that a top surface of the printhead die sliver is co-planar with a top surface of the dam), and/or printhead die attachment to the PCB, among other advantages.
The printbar 136 includes an arrangement of printheads 137 to dispense printing fluid on to a sheet or continuous web of paper or other print substrate 138. As described in detail below, each printhead 137 includes at least one printhead die sliver(s) 112 positioned in a recess (e.g., a recess 117 as illustrated in
The printhead die sliver 112 can be formed of semiconductor material (e.g., silicon) and can include integrated circuitry (e.g., transistors, resistors, etc.). Each printhead die sliver 112 includes ink feed holes, thin-film layer (including firing chambers), and conductors. A slot feeds printing fluid directly to the printhead die(s), such as to ink feed hole(s) included in the printhead die sliver 112. The ink feed holes provide printing fluid (e.g., ink) to fluid ejectors formed in the thin-film layer. Each printhead die sliver 112 includes an ejection chamber and a corresponding orifice through which printing fluid is ejected from the ejection chamber.
Each printhead die 112 receives printing fluid through a flow path from the printing fluid supplies 144 into and through the flow regulators 140 and slot(s) 116 in printbar 136 to ink feed hole(s) (not shown) included in the printhead die sliver 112. Notably, as described herein, the slot 116 extends through a PCB 14 and an adhesive material to the printhead die sliver 112. That is, the slot 116 is not prefabricated and advantageously promotes printhead die sliver 112 positioning and/or printhead die sliver adhesion, among other advantages. For example, the printbars of the present disclosure enable adhesive material to be continuously applied to a recesses and/or adhesive material to be located on a bottom surface of a printhead die sliver 112 without encountering issues associated therewith, such as undesired adhesive material migration (e.g., migration into the slot 116). Additional advantages associated with the printbar 136 include that the printbar does not have a fluidic fan-out component between the printheads 137 and the fluid supply, among other advantages.
The printbar 236 includes a PCB 214. The PCB 214 refers to a cured epoxy composition having conductive elements 213 (e.g., conductive signal traces and/or bond pads) included therein that can include particulate matter and/or structures (e.g., fiberglass structures, etc.) embedded in the epoxy, such as FR4 board. The PCB 214 is a continuous solid, as opposed to carrier boards that include prefabricated openings.
The PCB 214 includes a recess 217. The recess 217 extends partially into the PCB 214, for example, as illustrated in
Formation of a recess 217 can include removal of a portion of the PCB 214 designated to become the recess and/or addition of material to the PCB 214 surrounding an area of the PCB designated to become the recess, among other methods of forming the recess. For example, a recess, such as recess 217, can be formed prior to die attachment by addition of material to the PCB 214, such as a dam 221. That is, in some examples, the PCB 214 includes a dam 221 surrounding a perimeter of the recess 217. The dam can, for example, be located as around (e.g., forming a perimeter) of an area of the PCB 214 designated to be the recess 217. Such added material can be the same or dissimilar to a material(s) include in the PCB 214 prior to adding the additional material. For example, the additional material can, in some examples, include an additional epoxy layer of the same or dissimilar epoxy included in PCB 214 on which the additional material is placed.
The recess 217 can include an adhesive material, such as adhesive material 215, on (e.g., disposed on) a bottom surface 219 of the recess 217. The adhesive material, such as adhesive material 215, refers to an epoxy, among other adhesive materials suitable to form the printbar modules, as described herein.
In some examples, the adhesive material can include a continuous adhesive material disposed on the bottom surface 219 of the recess 217. Such a continuous application may not be possible in PCB 14 having a prefabricated opening(s) as the adhesive material would undesirably migrate into the prefabricated opening(s). However, continuous application of the adhesive material in accordance with some examples of the present disclosure promotes die adhesion and/or provides mechanical stability of a resultant printbar module employing the same, among other advantages.
While
The conductive elements 213 of the PCB 214 can be coupled, for example by wire bonds 222, to electrical circuits included in a printhead die structure (not shown), as described herein. Conductive elements 213 are analogous to conductive elements 313, 413, 513, 613, 713, and 813 as illustrated in
A molding 224 can encapsulate the wire bonds 222, the PCB 214, and/or the printhead die sliver 212. The molding 224 refers to a material that can protect the wire bonds 222, the PCB 214, and/or the printhead die sliver 212, such as an epoxy. Accordingly, such a molding can be applied and cured to protect the desired components. In some examples, the molding can be a monolithic molding compound, for instance, enabling multiple rows of printhead die slivers to be molded in a single, monolithic body on the PCB 214.
The PCB 214 includes a slot 216 form therein that extends through the PCB and an adhesive material 215 to the printhead die sliver 212. The slot 216 is not prefabricated and again advantageously promotes printhead die sliver 212 positioning and/or printhead die sliver adhesion, among other advantages. Formation of the slot is described in greater detail herein with respect to
Referring to
Printing fluid flows into each ejection chamber from a manifold extending lengthwise along each printhead die, for example, between the two rows of ejection chambers. Printing fluid feeds into manifold through multiple ports that are connected to a slot at printhead die surface. Slot is substantially wider (at least twice as wide as) than printing fluid ports that carry printing fluid from larger, loosely spaced passages in and/or to the flow regulators or other parts that carry printing fluid into printbar to the smaller, tightly spaced printing fluid ports in printhead die. Thus, slot can help reduce or even eliminate a discrete “fan-out” and other fluid routing structures. That is, a separate fluidic fan-out structure is not included between the manifold and the printhead die slivers. In addition, exposing a substantial area of printhead die sliver surface (e.g., an ink feed hole) directly to slot allows printing fluid in slot to help cool printhead die sliver during printing.
An actual printhead die sliver is typically a complex integrated circuit (IC) structure formed on a silicon substrate (not shown) with layers and elements not shown in
While
With regard to
Adhesive material can be applied to the PCB. For instance, the method can include applying an adhesive material to each of the plurality of recesses, as shown at 1191. Examples of the adhesive material include a flowable thermoset epoxy, among other adhesive materials suitable for application and printhead modules, as described herein. The adhesive material is applied to provide permanent adhesion of the die slivers to the PCB, as opposed to temporary adhesive material(s)/temporary adhesive products, for instance, temporary adhesion associated with thermal release tape and/or ultraviolet release tape, among other temporary adhesives materials and/or products utilizing temporary adhesive materials.
In some examples, the adhesive material is applied on both a bottom surface of the recess and/or side surfaces of a dam (e.g., surfaces of the adhesive material in contact with a side surface of the dam), such that, the adhesive material can attach a printhead die sliver to the PCB. For example, the adhesive material can be applied (e.g., continuously applied) to a bottom surface of each of the plurality of recesses and/or applied to a side surface (e.g., side surface as illustrated in
The adhesive material can be applied to the plurality of recesses and/or applied to a side surfaces of the dam using various techniques such as adhesive material stamping, stencil printing, and/or pin transfer, among other suitable techniques to apply the adhesive material as described herein. In some examples, applying adhesive material to the PCB includes applying adhesive material only to each of the plurality of recesses of the PCB. Such limited application can promote die positioning and/or provide a comparative reduction in cost associated with adhesive application (e.g., compared to coating the entire PCB), among other advantages. The adhesive material can be applied in a thickness and/or pattern suitable to promote positioning of the printhead die slivers.
For example, the method can include positioning a plurality of printhead die slivers in the plurality of recesses, as illustrated at 1192. Positioning can, in some examples, positioning the plurality of printhead die slivers within an adhesive material, such as adhesive material applied at 1191. The plurality of die slivers can be positioned with an orifice side facing down (towards a bottom surface of a recess) in the plurality of recesses. One of more of the plurality of die slivers can be positioned with each of the plurality of recesses. In some examples, a single die sliver of the plurality of die slivers is positioned within a single recess of the plurality of recesses. In this manner, a total number of the die slivers positioned in the recesses can equal a total number of the plurality of recesses. However, other positioning arrangements and/or total number of the plurality of printhead die slivers relative to a total number of the plurality of recesses are possible depending upon a desired type/performance of a resultant printbar module.
As illustrated at 1193 the method can include bonding the plurality of printhead die slivers with the PCB. For instance, the plurality of printhead die slivers positioned in the plurality of recesses, as illustrated at 1192, can be bonded to the PCB. Bonding can, in some examples, include wire bonds coupling conductive elements, such as conductive elements, of the PCB to conductive elements of the printhead die slivers. Wire bonds can include gold and/or copper bonds, among other suitable materials for forming wire bonds, for example, ball bond or wedge bonds coupling conductive elements of the PCB to conductive elements of the printhead die slivers.
The method can include encapsulating the plurality of printhead die slivers and/or the PCB with a molding, as illustrated at 1194. The mold can partially and/or completely encapsulate the plurality of printhead die slivers. For example, the plurality of printhead die slivers and/or the PCB can be encapsulated with a molding in response to bonding the plurality of printhead die slivers with the PCB. Encapsulating can include dispensing a liquid encapsulate material (e.g., an epoxy and/or an epoxy-based encapsulate material) over the printhead die slivers and/or and the wire bonds. In some examples, encapsulating can planarize the printhead die sliver, for instance, making a top surface of the printhead die sliver (e.g., a top surface of the molding located above a top surface of the printhead die sliver) co-planar with a top surface of a dam.
In response to encapsulating, for example, such as described with respect to 1194, the method can include forming a plurality of slots, extending through the PCB and the adhesive material, as illustrated at 1195. That is, the plurality of slots is formed after completion of encapsulating, as described herein. In various examples, encapsulating can include where the plurality of slots are in fluidic communication with fluid (e.g., ink) feed holes of the plurality of printhead die slivers to provide direct fluidic communication without fan-out, as described herein.
The adhesive material can remain on the bottom surface of the recess and a bottom surface of each of the plurality of printhead die slivers and/or between a side surface of the plurality of die slivers and a side surface(s) of a dam(s), such as dam. For instance, in some examples, forming can include forming the plurality of slots such that a portion of the adhesive material remains between the bottom surface 19 of the recess and a bottom surface of each of the plurality of printhead die slivers.
In some examples, forming includes forming the plurality of slots using a plunge-cut saw. However, the present disclosure is not so limited. That is, forming the plurality of slots, analogous or similar to slot 16, as described herein, can employ suitable chemical (e.g., chemical etching, etc.) and/or mechanical (e.g., drill, sand-blasting, laser, etc.) methods to form the plurality of slots.
The plurality of die slivers including printhead die sliver are not part of a single semiconductor substrate, but rather are formed from separate semiconductor substrates (note that the plurality of slivers can be formed on a single PCB and then singulated during manufacture to be assembled as part of printer). For example, the separate printhead die slivers can be positioned to provide an appropriate ink slot pitch that cooperates with a manifold (not shown) to receive the ink.
In an example, a width of each die sliver can be substantially narrower than a spacing between die slivers. Further, the thickness of each die sliver can be substantially thinner than a thickness of the PCB and/or a molding. In a non-limiting example, each die sliver is less than or equal to 300 micrometers. It is to be understood that the die slivers can have other thickness more than 300 micrometers.
As used in this document, a “micro device” means a device having at least one exterior dimensions less than or equal to 30 mm; “thin” means a thickness less than or equal to 650 μm; a “sliver” means a thin micro device having a ratio of length to width (L/W) of at least three; a “printhead” and a “printhead die” mean that part of an inkjet printer or other inkjet type dispenser that dispenses fluid from at least one openings. A printhead includes at least one printhead dies. “Printhead” and “printhead die sliver” are not limited to printing with ink and other printing fluids but also include inkjet type dispensing of other fluids and/or for uses other than printing. The terms “printbar” and “printbar module” as used herein is meant to encompass various print structures, such as page-wide modules, integrated printhead/containers, individual ink cartridges, and the like. While the present disclosures describes “ink” by way of example, it is to be understood that “fluid” can be used in place of “ink” wherever “ink” is specifically recited.
The specification examples provide a description of the applications and use of the system and method of the present disclosure. Since many examples can be made without departing from the spirit and scope of the system and method of the present disclosure, this specification sets forth some of the many possible example configurations and implementations. With regard to the figures, the same part numbers designate the same or similar parts throughout the figures. The figures are not necessarily to scale. The relative size of some parts is exaggerated to more clearly illustrate the example shown.
The present divisional patent application continuation application claims priority under 35 USC § 120 from copending U.S. patent application Ser. No. 15/113,533 filed on Jul. 22, 2016 by Chien et al. and entitled PRINTBARS AND METHODS OF FORMING PRINTBARS, which claims priority under 35 USC § 119 from PCT/US2014/013317 filed on Jan. 28, 2014 by Chien et al. and entitled PRINTBARS AND METHODS OF FORMING PRINTBARS, the full disclosures both of which are hereby incorporate by reference.
Number | Date | Country | |
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Parent | 15113533 | Jul 2016 | US |
Child | 16541410 | US |