The present disclosure is directed to a microfluidic die on a support with at least one other die.
Microfluidic die are being used in more and more diverse environments, different from the traditional use as a thermal inkjet die. In the more traditional uses, the inkjet die were typically mounted on a support by themselves. This was because the inkjet die were discarded, such as with the cartridge of ink when the ink had been used, while a relevant processor or application specific integrated circuit (ASIC) remained part of a printer. The ASICs and processors are more expensive to make and thus are not part of the disposable cartridges.
The present disclosure is directed to a variety of supports that provide a low cost solution to replace supports and flexible interconnects of traditional thermal inkjet systems and allow for inclusion of more than one die on a support. Each of the supports are configured to support a microfluidic die and one or more additional die including, but not limited to, other microfluidic die, ASICs, microelectromechanical systems (MEMS) devices, and sensors. The variety of supports includes semi-flexible supports that allow a microfluidic die to be at a 90 degree or other angle with respect to another die, and rigid supports that allow a microfluidic and another die to be in close proximity to each other.
According to one embodiment, a semi-flexible support includes a first rigid portion, a flexible portion, and a second rigid portion. The first rigid portion is separated from the second rigid portion by the flexible portion. The flexible portion may be fabricated by milling or thinning a specific portion of the semi-flexible support. By thinning the flexible portion, the semi-flexible support may be bent up to and beyond 90 degrees. A microfluidic die is positioned on the first rigid portion, and a second die, such as another microfluidic die, an ASIC, a MEMS device, or a sensor, and electrical contacts are positioned on the second rigid portion.
According to another embodiment, the semi-flexible support is cross or “t” shaped and includes a first rigid portion, a second rigid portion, a third rigid portion, a fourth rigid portion, and a flexible portion. The first, second, third, and fourth rigid portions are separated from each other by the flexible portion. The flexible portion allows the semi-flexible support to have up to four different bends up to and beyond 90 degrees. In one embodiment, a microfluidic die is positioned on each of the first rigid portion, the second rigid portion, the third rigid portion, the fourth rigid portion, and the flexible portion.
According to one embodiment, a rigid support provides a substantially inflexible substrate for a microfluidic die. In one embodiment, a packaged sensor including a sensor and an ASIC is mounted on the rigid support. In another embodiment, the sensor and the ASIC is coupled directly to the rigid support.
In the drawings, identical reference numbers identify similar elements. The sizes and relative positions of elements in the drawings are not necessarily drawn to scale.
In the following description, certain specific details are set forth in order to provide a thorough understanding of various embodiments of the disclosure. However, one skilled in the art will understand that the disclosure may be practiced without these specific details. In some instances, well-known details associated with semiconductors, integrated circuits, and microfluidic delivery systems have not been described to avoid obscuring the descriptions of the embodiments of the present disclosure.
Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment. Thus, the appearances of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.
In the drawings, identical reference numbers identify similar features or elements. The size and relative positions of features in the drawings are not necessarily drawn to scale.
The die 44 may also be a sensor that can detect environmental conditions relevant to the ejection of fluid by the microfluidic die, such as in a greenhouse environment. For example, if the sensor is a humidity sensor, the sensor can detect with the environment in the greenhouse is lower humidity than a threshold humidity and provide a control signal to the microfluidic die to eject water into the greenhouse. The die 44 may send a signal to a remote processor through the contacts 30 or could send the signal directly to the microfluidic die. The remote processor may be used if there are several different sensors in the environment from which a variety of signals are collected and evaluated before a control signal is provided to the microfluidic die, through the contacts 30.
The semi-flexible support 12 includes a first rigid portion 24, a flexible portion 26, and a second rigid portion 28. The first rigid portion 24 is separated from the second rigid portion 28 by the flexible portion 26. The first rigid portion 24 is positioned on a top of a cap 18 of the cartridge 14, and the flexible portion 26 is curved over an edge of the cap 18. The second rigid portion 28 is positioned on a sidewall of the cap 18, which is substantially perpendicular to the top of the cap 18. The semi-flexible support 12 further includes the electrical contacts 30 on the second rigid portion 28. The electrical contacts 30 and the semi-flexible support 12 will be discussed in further detail with respect to
In one embodiment, as shown in
It should be noted that although the die 44 and the electrical contacts 30 are illustrated at approximately a 90-degree angle with respect to the top of the cap 18, other angles are achievable depending on a design of the cap 18.
The cartridge 14 includes a reservoir 16 and the cap 18. The reservoir 16 stores fluid to be dispensed by the microfluidic die 10. The reservoir 16 may store any type of fluid, such as ink, water, fragrance oil, nutrients, and pesticides. The cap 18 encloses the reservoir 16. The reservoir 16 may be screwed in or snapped in to the cap 18. The cap 18 helps move liquid from the reservoir 16 to the microfluidic die 10 through an opening in the cap (not shown).
The microfluidic die 10 is configured to eject fluid from the reservoir 16 to an environment external to the fluid distribution system. The microfluidic die 10 includes nozzles 22; internal chambers; and other fluid elements, such as heaters or piezoelectric elements, that are configured to be driven by signals from the electrical contacts 30 to eject fluid from the internal chambers through the nozzles 22. The microfluidic die 14 may include any number of nozzles 22, and the nozzles 22 may have any arrangement. The microfluidic die 14 may dispense any type of fluid, such as ink, water, fragrance oil, nutrients, and pesticides.
An encapsulant 20 covers and protects conductive wires coupled to the microfluidic die 10, while leaving the nozzles 22 exposed. Each of the nozzles 22 provides a fluid path to eject fluid from internal chambers of the microfluidic die 10 to an environment external to the fluid distribution system. The microfluidic die 10 may include any number of nozzles 22, and the nozzles 22 may have any type of arrangement.
Although not shown, the microfluidic die 10 also includes a plurality of electrical traces on the microfluidic die 10 that are coupled to the conductive wires to receive signals to drive the ejection of fluid. The drive signals may be provided from another die, such as the die 44 or an external processor that send the drive signals through the electrical contacts 30.
The die 44 is shown as a packaged die with wires 41 that couple to contacts 33 on a first side 32 of the support. These wires may be exposed or may be covered by encapsulant. As noted above, the die 44 may be any type of die, including, but not limited to, a MEMS device and a sensor, such as a temperature, humidity, pressure, and light sensor.
By positioning the microfluidic die 10 and the die 44 on the semi-flexible support 12, the microfluidic die 10 and the die 44 may share the same electrical interconnect system. For example, as will be discussed in further detail below, the microfluidic die 10 and the die 44 may both be electrically coupled to electrical contacts 30. In addition, the microfluidic die 10 and the die 44 may be positioned in close proximity to each other. This is ideal for sensors that need to be in close proximity to the microfluidic die 10 to obtain useful and accurate measurements. Further, integrating the die 44 on the same support as a microfluidic die 10 allows the die 44 and the microfluidic die 10 to be replaced concurrently, thus reducing intervention rate and presumably maintenance costs. This is well suited for die that have finite life, such as sensors containing a chemical reactive.
The first rigid portion 24 has a width 25 and the second rigid portion 28 has a width 27. The widths 25 and 27 may be adjusted based on a size and shape of a cap or other object on to which the semi-flexible support 12 will be placed. For example, as shown in
The electrical contacts 30 are electrically coupled to the microfluidic die 10 and the die 44. The electrical contracts 30 allow external devices to be electrically coupled to the microfluidic die 10 and the die 44. The electrical contacts 30 may be electrically coupled to the microfluidic die 10 and the die 44 through any number of standard wire bond type connections. The semi-flexible support 12 may include any number of electrical contacts and may have any type of arrangement. In one embodiment, as shown in
The electrical contacts 30 are electrically coupled to the microfluidic die 10 by the conductive wires 38. As best shown in
The fluid opening 40 extends through the first rigid portion 24 and underlies the microfluidic die 10. The fluid opening 40 provides a fluid path through the semi-flexible support 12 such that fluid may flow from the reservoir 16, through the cap 18 and the fluid opening 40, and to the microfluidic die 10.
In the same or another embodiment, the semi-flexible support 12 further includes protective layers 29. The protective layers 29 are configured to protect the semi-flexible support 12 from any external damage. The protective layers 29 may be formed on the first side 32, the second side 34, or both the first side 32 and the second side 34 of the semi-flexible support 12. In another embodiment, the semi-flexible support 12 is fabricated without the protective layers 29. The protective layers 29 may be made of silicon dioxide or any other suitable dielectric. The protective layers 29 may be solder masks.
The semi-flexible support 12 may be made of any type material that provides a rigid substrate. For example, the semi-flexible support 12 may be made of glass, silicon, or a printed circuit board (PCB), such as a FR4 PCB.
The flexible portion 26 of the semi-flexible support 12 may be fabricated by milling or thinning a specific portion of the semi-flexible support 12. Namely, as best shown in
In the embodiment shown in
In one embodiment, the semi-flexible support 12 is flexed around a fluid line 42 of a fluid distribution system 43. The fluid line 42 is configured to simultaneously provide fluid to both of the microfluidic die 10, 11. The fluid distribution system includes arms or brackets 45a, 45b that hold a first end 47 and a second end 49 of the semi-flexible support 12 in place. These brackets ensure that the fluid line 42 lines up with and is in fluid communication with the microfluidic die 10, 11. The bracket 45b overlaps the electrical contacts 30 and electrical components (not shown) to transmit or receive signals from the contacts 30 to and from a processor or ASIC associated with the fluid distribution system. These brackets 45a, 45b, allow the support to be removed and replaced if needed, such as if the die have a limited life, i.e. the nozzles get clogged after a period of time of use.
In contrast to the semi-flexible support 12, the semi-flexible support 46 is cross or “t” shaped. In particular, the semi-flexible support 46 includes a first rigid portion 48, a second rigid portion 50, a third rigid portion 52, a fourth rigid portion 54, and a flexible portion 56, these can be thought of as arms or branches from a central flexible portion 56. The first, second, third, and fourth rigid portions 48, 50, 52, and 54 are separated from each other by the flexible portion 56. As best shown in
In one embodiment, as shown in
The electrical contacts 30 are positioned on the first rigid portion 48. As previously discussed, the electrical contacts 30 are electrically coupled to the microfluidic die 10 by conductive wires embedded within the semi-flexible support 46. As previously discussed with respect to the conduct wires 38, the conductive wires are embedded with the semi-flexible support 46 to allow a portion of the semi-flexible support 40 to be removed to fabricate the flexible portion 56.
The flexible portion 56, similar to the flexible portion 26, is fabricated by milling or thinning a specific portion of the semi-flexible support 46 such that the first, second, third, and fourth rigid portions 48, 50, 52, and 54 each has a thickness that is greater than the flexible portion 56. By thinning the flexible portion 56, the semi-flexible support 46 may have up to four different bends up to and beyond 90 degrees. For example, as shown in
The semi-flexible support 46 may be flexed in a variety of positions, and thus eject fluid in a variety of different directions. For example, the semi-flexible support 36 may have a single bend, two bends, or three bends to create any number of increasingly complex shapes.
The semi-flexible support 46 may also have other shapes. For example, in one embodiment, the semi-flexible support 46 is composed of twelve five-sided pentagons of equal size and eleven bends to create a pentagon ball. One or more microfluidic die may then be placed on any of the exterior surfaces of the pentagon ball to eject fluid outwards in all directions.
The rigid support 60 provides a substantially inflexible substrate for a microfluidic die 10. Similar to the semi-flexible supports 12 and 46, the microfluidic die 10 is positioned over a fluid opening extending through the rigid support 60 to provide a fluid path through the rigid support 60. For example, see the fluid opening 40 shown in
The rigid support 60 may be made of any type material that provides a rigid substrate. For example, the rigid support 60 may be made of glass, silicon, or a printed circuit board (PCB), such as a FR4 PCB.
The rigid support 60 includes electrical contacts 30 and through holes 62. As previously discussed, the electrical contacts 30 are electrically coupled to the microfluidic die 10 and allow external devices to be electrically coupled to the microfluidic die 10. The through holes 62 are configured to receive a through hole mount connector 64, which will be discussed in further detail below.
The packaged sensor 58 includes a through hole mount connector 64, a sensor 66, an ASIC 68, and a cover 70.
The through hole mount connector 64 couples the packaged sensor 58 to the rigid support 60 by inserting leads 72 of the through hole mount connector 64 into the through holes 62. It should be noted that other methods may be used to couple the packaged sensor 58 to the rigid support 60. For example, in another embodiment, the through hole mount connector 60 is replaced with a ball grid array (BGA) mount.
The sensor 66 is positioned on the through hole mount connector 64. The sensor 66 may be any type of sensor, such as a temperature, humidity, pressure, and light sensor.
The ASIC 68 is positioned on the sensor 66. In another embodiment, the ASIC 68 is positioned on the through hole mount connector 64, lateral to the sensor 66. In one embodiment, the ASIC 68 is configured to control the microfluidic die 10 and the sensor 66.
The cover 70 is coupled to the through hole mount connector 64, covering the sensor 66 and the ASIC 68. The cover 70 provides protection for the sensor 66 and the ASIC 68 from external sources, such as fluid being ejected from the microfluidic die 10.
In one embodiment, the sensor 66 and the ASIC 68 are electrically coupled to the leads 72 by conductive wires 74. In the same or another embodiment, the microfluidic die 10, the electrical contacts 30, and the through holes 62 are electrically coupled to each other.
The microfluidic die 10, the packaged sensor 58, and the electrical contacts 30 may be positioned in multiple different configurations. For example, in one embodiment, as shown in
In another embodiment, the sensor 66 and the ASIC 68 are mounted directly to the rigid support 60, without the through hole mount connector 60.
At a step shown in
At a step shown in
At a step shown in
At a step shown in
The microfluidic die 10, the sensor 66, the ASIC 68 may be coupled to the rigid support 60 in any order. In one embodiment, the microfluidic die 10 is coupled to the rigid support 60 prior to the sensor 66 and the ASIC 68. In another embodiment, the order of operating depends on the relative value of the components. For example, the components with the highest value may be coupled to the rigid support 60 last.
In accordance with one or more embodiments, the semi-flexible supports and the rigid supports provide a low cost solution to replace supports and flexible interconnects of traditional thermal inkjet systems. Each of the supports are configured to support a microfluidic die and one or more additional die including, but not limited to, microfluidic die, ASICs, MEMS devices, and sensors. In one or more embodiments, the supports are configured to support multiple microfluidic die to eject fluid in multiple different directions. In one or more embodiments, the supports are configured support a microfluidic die in close proximity to another die.
The various embodiments described above can be combined to provide further embodiments. These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.
Number | Date | Country | |
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62273260 | Dec 2015 | US |
Number | Date | Country | |
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Parent | 15253618 | Aug 2016 | US |
Child | 16179808 | US |