The present disclosure relates to a microfluidic device for spraying small drops of liquids.
As is known, for spraying inks and/or perfumes or the like, the use has been proposed of microfluidic devices of small dimensions, which may be obtained with microelectronic manufacturing techniques.
For example, U.S. Pat. No. 9,174,445 describes a microfluidic device suitable for thermally spraying ink on paper.
The cell 11 shown in
A nozzle 15 is provided through the nozzle plate 14 and has a first portion 15A, facing the fluid containment chamber 19, and a second portion 15B, facing in the opposite direction (towards the outside of the microfluidic device 10). The first portion 15A is significantly wider than the second portion 15B. A heater 20 is provided within the thin layer 13, adjacent to the fluid containment chamber 19 and vertically aligned to the nozzle 15. The heater 20 may have an area of approximately 40×40 μm2 and generate, for example, an energy of 3.5 μJ, and is able to reach a maximum temperature of 450° C. in 2 μs.
The fluid containment chamber 19 is further provided with a fluidic access 21 that enables inlet and transport of the liquid inside the fluid containment chamber 19, as indicated by an arrow L. A plurality of columns, not visible in
The microfluidic device 10 may comprise a plurality of cells 11 connected, through the fluidic accesses 21, to a liquid-supply system (not shown).
Another type of microfluidic device suitable for thermal spraying fluids is based upon the piezoelectric principle. An embodiment of a microfluidic device 30 of this type is described, for example, in US 2014/0313264 and is shown in
The microfluidic device 30 of
The bottom portion is formed by a first region 32, of semiconductor material, having an inlet channel 40.
The intermediate portion is formed by a second region 33, of semiconductor material, which laterally delimits a fluid containment chamber 31. The fluid containment chamber 31 is further delimited at the bottom by the first region 32 and at the top by a membrane layer 34, for example of silicon oxide. The area of the membrane layer 34 above the fluid containment chamber 31 forms a membrane 37. The membrane layer 34 has a thickness that allows it to deflect, for example, by approximately 2.5 μm.
The top portion is formed by a third region 38, of semiconductor material, which delimits an actuator chamber 35, overlying the fluid containment chamber 31. The third region 38 has a through channel 41, in communication with the fluid containment chamber 31 through a corresponding opening 42 in the membrane layer 34.
A piezoelectric actuator 39 is arranged over the membrane 37, in the actuator chamber 35. The piezoelectric actuator 39 is formed by a pair of electrodes 43, 44, arranged on top of each other, and an intermediate layer of piezoelectric material 29, for example PZT (Pb, Zr, TiO3).
A nozzle plate 36 is arranged on top of the third region 38, bonded thereto by a bonding layer 47. The nozzle plate 36 has a hole 48, arranged over, and fluidically connected with, the channel 41 through an opening 46 in the bonding layer 47. The hole 48 constitutes a nozzle of a drop emission channel, designated as a whole by 49 and comprising also the through channel 41 and the openings 42, 46.
In use, the fluid containment chamber 31 is filled with a fluid or liquid to be ejected through the inlet channel 40. Then, in a first step, the piezoelectric actuator 39 is controlled so as to cause deflection of the membrane 37 towards the inside of the fluid containment chamber 31. This deflection causes a movement of the fluid present in the fluid containment chamber 31 towards the drop emission channel 49, and generates controlled expulsion of a drop, as represented by the arrow 45. In a second step, the piezoelectric actuator 39 is controlled in the opposite direction so as to increase the volume of the fluid containment chamber 31, recalling further fluid through the inlet channel 40.
In either case (thermal or piezoelectric actuation), current microfluidic devices are able to generate drops of medium-to-large size, which exceed considerably the desired size for use as nebulizers.
For example, current high density print heads (up to 1200 dpi) produce drops of a minimum size of two picolitres (2 pl=2·1015 m3), which correspond to spherical drops having a diameter of approximately 7.8 μm. At present, with current technologies, it is possible to produce nozzles with a minimum size of approximately 6 μm. For nebulizers, on the other hand, it is desired to generate drops of smaller diameter, as small as 1 μm, corresponding to a volume of approximately 0.0045 pl (4.5·10−18 m3). To do this, it would be necessary to have nozzles of sublithographic diameter, i.e., of dimensions much smaller than those obtainable with the current photolithographic technology used in the manufacture of semiconductors.
One or more embodiments are directed to a device configured to eject a fluid with small droplets. According to one embodiment of the present disclosure, a microfluidic device is provided. The microfluidic device comprises a body housing a fluid containment chamber, a fluidic access channel, a drop emission channel, and an actuator. The fluid access channel is in fluidic connection with the fluid containment chamber. The drop emission channel is configured to provide a fluidic path between the fluid containment chamber and a body outside. The drop emission channel comprises a nozzle forming an outlet section having a first area. The drop emission channel comprises a portion of reduced section having an area smaller than the first area. The actuator is operatively coupled to the fluid containment chamber and configured to cause ejection of drops of fluid through the drop emission channel in an operating condition of the microfluidic device.
For a better understanding of the present disclosure, preferred embodiments thereof are now described, purely by way of non-limiting example, with reference to the attached drawings, wherein:
The present device is based upon the principle of forming a portion of the drop emission channel with an effective cross-section having a smaller area than the cross-section of the rest of the drop emission channel. This is obtained by forming a part of the drop emission channel (for example, the nozzle) partially offset with respect to the rest of the drop emission channel, overlying it or underlying it. In practice, in the present device, the area of the nozzle and the area of the rest of the drop emission channel have a non-zero intersection which has a smaller area than the entire nozzle area. In this way, it is possible to obtain a choking in the drop emission channel, i.e., a useful drop emission area which is smaller than the one achievable with existing or future manufacturing techniques.
The above principle is highlighted by comparing
In
The cell 51 may be manufactured as shown in
In the cell 51, a heater 53 is formed within the insulating layer 61 and forms an actuator. The fluid containment chamber 52 is formed within the chamber layer 63, above the heater 62, facing the insulating layer 61. The fluid containment chamber 52 here has a parallelepipedal shape with approximately rectangular base, parallel to a plane XY of a Cartesian system XYZ, with a height (in the direction Z) smaller than the thickness of the chamber layer 63. The fluid containment chamber 52 is laterally delimited by walls 65 that define a lateral surface of the fluid containment chamber 52. The fluidic access 66, formed in the chamber layer 63, connects the fluid containment chamber 52 with a fluid supply channel 67, schematically represented in
The nozzle 54, which here has a cylindrical shape with circular base, is formed in the top part of the chamber layer 63 and is arranged at one corner of the fluid containment chamber 52, so that a portion of the surface of the walls 65 extends through its base area. In particular, the intersection 54 here has an area that is approximately one quarter of the base area of the nozzle 54.
The cell 51 may be manufactured by initially forming, on the substrate 60, a sacrificial structure having a shape corresponding to the fluid containment chamber 52, of the fluidic access 66, and of the fluid supply channel 67, then depositing polymeric material intended to form the chamber layer 63. In particular, the chamber layer 63 may be formed using lamination and reflow techniques, in a per se known way in the microinjector technique. Next, the chamber layer 63 is perforated, via selective etching and using common photolithographic techniques, to form the nozzle 54.
Alternatively, the chamber layer 63 may be separately molded and bonded on the insulating layer 61, or formed in a dug silicon structure, bonded to the insulating layer 61. According to a different embodiment, the chamber layer 63 may be formed by two separate layers or regions, glued together.
The intersection 54 causes the useful area of the nozzle 54 to be reduced as compared to its physical dimensions obtainable with the current lithographic definition processes, and allows obtainment of drops of smaller dimensions as compared to devices micromachined using the same technology, as shown also in the simulations of
The fluid containment chamber 52 may form part of an array of drop-generation chambers 52 arranged side by side and connected to a same fluid supply channel 67, as shown in
The nozzle 54 and the fluid containment chamber 52 may have different shapes and mutual arrangements. For example, the fluid containment chamber 52 may have a cylindrical or polyhedral shape as desired, whether regular or irregular, with the nozzle arranged so as to intersect (in top plan view) the circumference or perimeter of the base. Further, a number of nozzles may be provided for each fluid containment chamber.
For example,
Also in the cells 51B-51D a reduction in volume of the drops emitted is then obtained, without excessively penalizing the emitted liquid density.
Finally, it is clear that modifications and variations may be made to the microfluidic device described and illustrated herein, without thereby departing from the scope of the present disclosure. For example, the different embodiments described may be combined so as to provide further solutions.
Further, the shape of the nozzle base may differ from the one shown; for example, it may be oval or polygonal.
In the microfluidic device with piezoelectric actuation, the reduction of the useful section could be obtained at the inlet mouth of the through channel 41, by appropriately staggering the mouth of the channel 41 with respect to the fluid containment chamber 31.
Further, also in the microfluidic device with piezoelectric actuation, the fluid containment chamber 35 may have any shape, for example a polyhedral shape having a base with projecting vertices, points, or portions. Also in this case, the fluidic path may comprise a plurality of nozzles partially overlapping the projecting vertices, points, or portions, so as to form intersections of reduced area.
Also for the microfluidic device with piezoelectric actuation, it is possible to arrange a plurality of cells of the type shown in
Further, in all the microfluidic devices, the fluid containment chamber may have a cylindrical shape with circular or oval base, and the nozzle or nozzles may be arranged straddling the circumference of the circular or oval base.
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 | Kind |
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102016000118584 | Nov 2016 | IT | national |
Number | Date | Country | |
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Parent | 15601623 | May 2017 | US |
Child | 17381079 | US |