The present disclosure is related generally to droplet generation 2D and 3D printing technology and more specifically to acoustophoretic printing.
Due to the limitations of state-of-the-art 2D and 3D printing methods, inks are often engineered to have physical properties satisfying the requirements of existing printers. A typical approach to rendering materials printable is to use additives to adjust the rheological properties of the ink. While enhancing printability, such additives may act as impurities in or otherwise prove detrimental to the printed structure.
In the realm of droplet-based printing techniques, inkjet technology represents a standard in industry and research. Despite its wide usage, only a narrow window of materials having a suitable combination of properties (e.g., viscosity and surface tension) may be successfully ejected from an ink jet printhead. This limitation can be attributed to the droplet detachment mechanism, which is based on the Rayleigh-Plateau instability. In inkjet technologies, a substantial mechanical excitation of the ink may be required in order to break the meniscus and eject a defined volume of liquid. Such a dynamic process implies a strong coupling between interfacial and viscous forces. From a physical point of view, the droplet generation of a defined ink can be characterized by a non-dimensional number, the Ohnesorge number Oh, and its inverse Z=Oh−1=(ρσ2R)1/2/μ, with R being the characteristic length of the droplet, ρ the density of the liquid, σ its surface tension, and μ its viscosity of the ink. Unsurprisingly, the scientific literature reports that successful printing requires that the physical properties of the ink produce a Z value in a narrow window (1<Z<10).
Many inks of practical interest are based upon colloids or polymers that have relatively high viscosity and require dilution with additives for successful printing. Truly decoupling the dependence of the printing process from the physical properties of the ink may allow unprecedented freedom in the type and complexity of materials that can be 2D- and 3D-printed. A description of preliminary work to solve this problem may be found in Foresti et al., “Acoustophoretic Printing Apparatus and Method,” International Publication No. WO 2015/110600, which is hereby incorporated by reference in its entirety.
An apparatus for acoustophoretic printing comprises: an acoustic chamber fully or partially enclosed by sound-reflecting walls for transmission of an acoustic field; an emitter at a first end of the acoustic chamber for generating the acoustic field; a chamber outlet at a second end of the acoustic chamber for locally enhancing the acoustic field and transmitting the acoustic field out of the acoustic chamber; and a nozzle in the acoustic chamber having a nozzle opening projecting into the chamber outlet for delivery of an ink into a high-intensity acoustic field and out of the acoustic chamber.
A method of acoustophoretic printing comprises generating an acoustic field at a first end of an acoustic chamber fully or partially enclosed by sound-reflecting walls. The acoustic field interacts with the sound-reflecting walls and travels through the acoustic chamber. The acoustic field is enhanced in a chamber outlet at a second end of the acoustic chamber. An ink is delivered into a nozzle positioned within the acoustic chamber. The nozzle has a nozzle opening projecting into the chamber outlet. The ink travels through the nozzle and is exposed to the enhanced acoustic field at the nozzle opening, and a predetermined volume of the ink is ejected from the nozzle opening and out of the acoustic chamber.
Acoustophoretic printing is an innovative approach for 2D- and 3D printing and may have application in a wide range of fields. The technology exploits the nonlinear effects of a subwavelength ultrasonic cavity to control droplet detachment from a nozzle by harnessing acoustic radiation pressure acting on the droplet. By exploiting Fabry-Perot acoustic resonances, as explained below, it may be possible to: (1) generate an acoustic field that intrinsically outcouples the detached drop; 2) create a highly localized acoustic field, which decouples the force from an underlying substrate; and 3) enhance the acoustic force magnitude by more than one or two orders of magnitude compared to existing systems. Advantages of the acoustophoretic printing approach described in this disclosure may include: 1) independence from any electromagnetic/optical properties or composition of the ink; 2) ink-viscosity independence; and 3) coverage of a droplet volume range exceeding two orders of magnitude with a single nozzle size.
Referring to
As shown in
The chamber outlet 108 may have a width or diameter dh and a height Hh, as indicated in
The achievement of a resonant condition in the chamber outlet or subWAVE 108 may be exhibited by an enhancement in acoustic pressure.
Referring now to
In contrast to traditional standing wave levitators, the subWAVE 108 allows for ejection of the detached droplet from the acoustic chamber 102, as shown schematically in
Since acoustophoretic printing can generate acoustic forces (Fa) more than two order of magnitude higher than the gravitational force (Fg), the ballistic trajectory of the ejected droplet allows for accurate printing even in a direction orthogonal to the force of gravity, as mentioned above. Indeed, for a substrate 116 positioned within 1-3 mm from the chamber outlet 108, gravitational effects on the droplet trajectory are minimal. Experiments in which an ink comprising a water-glycerol mixture (50%) is ejected from a chamber outlet 108 along a trajectory orthogonal to the direction of gravity show that, when Fa>10 Fg, the trajectory is poorly influenced by the gravitational force up to several millimeters from the nozzle opening 112. Since the subWAVE 108 need not be oriented such that ejection of the droplet occurs in the vertical (downward) direction, as defined by the force of gravity, the term “vertical force” used herein may be understood to refer more generally to an acoustic ejection force that may act in a vertical or other direction to expel the droplet from the exit 114 of the subWAVE 108.
Fabry-Perot resonance may be understood to be a manifestation of constructive or destructive acoustic wave interference over a certain path length that can lead to multiple transmission peaks. In the present case, a subwavelength resonance is generated in the chamber outlet 108 (in addition to the primary standing wave in the acoustic chamber 102) may lead to an enhancement in the acoustic field. A small departure from the optimal dimensions of a Fabry-Perot resonator can strongly reduce the acoustic field and thus the vertical force inside the subWAVE 108.
The acoustic chamber 102 may include a sound-reflecting side wall 104s at the second end to facilitate formation of a velocity antinode 120a in the acoustic field adjacent to the chamber outlet 108.
As indicated above, the acoustic chamber 102 may be partially or fully enclosed by the sound-reflecting walls 104. Advantageously, the acoustic chamber 102 includes at least two or at least three sound-reflecting walls and as many as six or more sound-reflecting walls. For example, the acoustic chamber 10 may include a sound-reflecting top wall 104t adjacent to the acoustic emitter 106 and a sound-reflecting bottom wall 104b in opposition to the acoustic emitter 106. The sound-reflecting walls may be formed of any of a number of solid materials, including metals, ceramics, polymers, natural fiber materials (e.g., wood, paper), plaster, and others. The acoustic chamber may have a rectangular parallelepiped shape, as shown for example in
The acoustic field generated in the acoustic chamber 102 may be highly dependent on the dimensions of the chamber 102, including the distance dx between the emitter 106 and the chamber outlet 108, the height of the emitter 106 (emitter height HE), the height of the sound-reflecting top wall 104t (reflector height HR), and the distance dwall between the chamber outlet 108 and the sound-reflecting side wall 104s. The distance dwall is shown schematically in
The acoustic chamber may include a fluid medium, i.e., a gas or liquid such as ambient air, water or oil, which can transmit sound waves. The acoustic chamber may be immersed in the fluid medium. In some cases, the fluid medium may be forced through the acoustic chamber at a constant or variable flow rate.
The nozzle 110 may take the form of a glass pipette or other fluid conduit that has a length sufficient to pass through the interior of the acoustic chamber 102 and into the chamber outlet 108. The nozzle 110 may include a nozzle opening 112 having a diameter in the range from about 1 micron to about 1 mm, and more typically from about 10 microns to about 100 microns. To prevent wetting of the nozzle during printing, the nozzle 110 may include a hydrophobic coating at or near the nozzle opening 112. Typically, the nozzle opening 112 is substantially centered within the chamber outlet (e.g., substantially aligned with a longitudinal axis of the chamber outlet) 108 as shown in
As indicated above, the chamber outlet 108 may take the form of a through-thickness cavity 118 in one of the sound-reflecting walls 104 of the acoustic chamber 102. Referring to
The chamber outlet 108 may have a cylindrical geometry, as shown by the image of
In addition to an apparatus for acoustophoretic printing, a method of acoustophoretic printing is described herein. The method may entail generating an acoustic field at a first end of an acoustic chamber fully or partially enclosed by sound-reflecting walls. The acoustic field interacts with the sound-reflecting walls and travels through the acoustic chamber, ultimately being transmitted through a chamber outlet at a second end of the acoustic chamber. The acoustic field is enhanced in the chamber outlet, which functions as a subwavelength resonator or subWAVE, as explained above. An ink is delivered into a nozzle positioned within the acoustic chamber that has a nozzle opening projecting into the chamber outlet. The ink travels through the nozzle to the nozzle opening and is exposed to the enhanced acoustic field in the chamber outlet. A predetermined volume of the ink may thus be ejected from the nozzle opening and out of the acoustic chamber. The chamber outlet or subWAVE may achieve a resonant condition that strongly enhances the acoustic field and provides an acoustic force to facilitate droplet detachment and ejection from the chamber. The acoustic resonance may be referred to as a Fabry-Perot resonance, as explained above.
Advantageously, the acoustic field comprises a velocity antinode at the second end of the acoustic chamber adjacent to the chamber outlet. The acoustic field may further comprise a plurality of the velocity antinodes between the first end and the second end of the acoustic chamber. To exploit the presence of multiple velocity antinodes, the acoustic chamber may include a plurality of chamber outlets, where each chamber outlet is positioned adjacent to (e.g., below) one of the velocity antinodes, and a plurality of the nozzles, where each nozzle has a nozzle outlet projecting into one of the chamber outlets.
The acoustic field may be generated by an emitter, which may take the form of a piezoelectric transducer, a metal oscillator or another source of sound waves. A suitable driving frequency may be in the range from 1 kHz to 2 MHz, and more typically from 20 kHz to 250 kHz. At a suitable driving frequency, a resonant condition corresponding to a high acoustic pressure may be achieved in the chamber outlet.
The acoustic field generated in the acoustic chamber may be highly dependent on the dimensions of the acoustic chamber as described above and in the examples. Consequently, controlling the dimensions of the acoustic chamber may provide a tool for adjusting and selecting the size of the ejected droplets. Additionally, for a given size and/or geometry of the acoustic chamber, the size of the ejected droplets may be controlled by varying the emitter amplitude.
Droplet generation, ejection (or outcoupling) from the acoustic chamber, and droplet trajectory control are important aspects of acoustophoretic printing. Printing accuracy is influenced by the distance between the nozzle opening and the substrate, and the magnitude of acoustophoretic forces. Ballistic ejection of the droplet is confirmed by the exit angle error, which remains mostly constant at different nozzle-substrate distances, as shown in
Possible applications for acoustophoretic printing include optics, microfluidics, bioprinting, food manufacturing and stretchable electronics. Given the wide range of ink material capability, drop-on-demand (DOD) features, and robustness, acoustophoretic printing can be employed to realize a diverse array of materials and products.
Additive manufacturing for food is a growing and novel market and field of research, while honey represents a typical lay example of a viscous fluid; being able to DOD print such a fluid without any kind of chemical, physical, thermal or electric adulteration represents a litmus test of the process described in this patent document.
Compound eyes are well known for their infinite depth of field and wide field of view. Nevertheless, their artificial counterparts—microlens arrays—are characterized by cumbersome fabrication, especially in 3D forms.
In human-tissue engineering, a prototypical printing of human mesenchymal stem cells (hMSC) in collagen is presented in
In the high Z-number range, low viscosity and high surface tension inks such as liquid metals can be printed.
As the above examples show, the ink may be successfully printed over a wide range of Z values (e.g., from 0.001 to 1000). In specific embodiments, the ink may have a value of Z from 0.001 to less than 1, from 1 to 10, or from greater than 10 to 1000. Among the large range of inks that may be successfully printed are synthetic and naturally-derived biocompatible materials with or without cells (e.g., human cells such as stem cells, primary cells or other cell types), electrically or ionically conductive materials such as liquid metals (e.g., EGaln), and polymers such as adhesives, hydrogels, elastomers and others. It should be noted that some polymers may be biocompatible and/or conductive. For example, polymers such as polyaniline and ionically conductive hydrogels are intrinsically conductive, and other “extrinsically conductive” polymers may be rendered conductive by additives, such as metal particles. Polymers such derived from collagen, hyaluronate, fibrin, alginate, agarose, chitosan or gelatin, for example, may be biocompatible. Suitable inks may also or alternatively include drugs, pharmaceutical agents and/or food products.
Physical Principle
To understand the advantage of employing a high-intensity acoustic field during 2D or 3D printing, the basic physical principle behind (ink) droplet detachment is explained here. Referring to
In such a system, the flow through the nozzle is decoupled from droplet detachment. The gravity force acts as a body force and an external force compared to the nozzle/reservoir system. Viscosity plays little role in this quasi-static approximation, and it does not appear in the equilibrium equation V*=ρ/σ/ρ. This decoupling allows ink droplets of practically any viscosity to be ejected from a nozzle when dealing with Newtonian fluids.
To decrease the droplet size at detachment, two options are possible: the fluid properties, σ/ρ, may be acted on, or d may be acted on. The former approach may be more limiting, since σ and ρ are usually of the same order of magnitude for most liquids of interest and, additionally, it is not consistent with a material-independent ejection concept. The nozzle diameter d can be varied from the millimeter size range down to the submicron size range, allowing for a linear decrease of V*, as illustrated in
The force on the droplet arises from the radiation pressure, which is a nonlinear effect of the acoustic field. Acoustophoretic forces are essentially material independent when handling liquid or solid samples in air. In particular, when dealing with spherical objects (i.e. a drop) in an acoustic standing wave configuration, the acoustophoretic forces scales as Fa∝R3p2∝Vp2, with p being the acoustic pressure. This scaling highlights three important aspects: 1) no property information is needed regarding the sample material since the forces are material independent; 2) the acoustic forces are strongly dependent on the acoustic pressure; 3) since gravitational forces are also proportional to V, an equivalent (augmented) acoustic acceleration ga can be introduced.
Fc=πσd=Fg+Fa=V*ρ(g+ga)→V*=πdσ/ρgeq (1)
Equation 1 illustrates acoustophoretic droplet generation in all its simplicity and power. Since Fa∝ga∝p2, for any liquid or nozzle V*∝1/p2.
With its inherent independence of viscous material properties, acoustophoretic printing enables droplet generation from inks of disparate classes. Acoustophoretic printing can generate droplets in a Z-range that extends the state of the art by more than four orders of magnitude; such a capability may allow a much wider swath of materials to be printed in a contactless droplet-based fashion, enabling new possibilities in the realm of functional printing. Since the droplet detachment is not dependent on interfacial breakup, acoustophoretic printing is indeed little affected by the ink viscosity. In order to showcase this characteristic, deionized water and a polymer solution (Poly Ethylene Glycol, PEG molecular weight 8000) are continuously mixed to span three orders of magnitude of ink viscosity, from μ=1 mPas to 1000 mPas.
Experimental and Computational Details
Acoustic Chamber Design
As discussed above, the acoustic field generated in the acoustic chamber is highly dependent on the dimensions of the acoustic chamber. Once the dimensions of the acoustic chamber are set based on the size of the emitter and the space needed for the nozzle(s), the emitter height HE and the reflector height HR can be considered.
In order to characterize the acoustic chamber and identify the optimal values of HE and HR, dwall is set to 1.2 mm and kept constant for all measurements, corresponding to dwall=0.9λ (here, λ=14 mm). Simulations are performed where both dimensions are varied. The result is a matrix of acoustic pressure in Pascal as a function of HR and HE, which is shown in a contour plot in
The modeling of the acoustic field identifies values of HE and HR that may lead to an optimal acoustic field in the subWAVE. To study the influence of HE and HR and on the acoustic field experimentally, measurements of the acoustic pressure field are performed with a microphone. The microphone is placed outside the acoustic chamber, coaxial to the chamber outlet (subWAVE) at a distance of 8 mm from the subWAVE exit. The experimental setup used is shown in
HE and HR are varied between 0.48λ-0.56λ and 0.5λ-0.58λ respectively with 0.07λ increments. The measurements are repeated three times and the parts are disassembled and reassembled between each set of measurements. The final result is a 12×12 matrix which is a function of HE and HR and is shown in a contour plot in
Varying HE and HR provides a powerful tool to adjust and choose the size of the ejected droplets. In this study, the highest acoustic field intensity—which is believed to result in the smallest possible droplet size during printing—is found to occur with HE and HR set to P2=(0.575λ, 0.537λ). P2 has a broader peak than P1, providing more room for maneuver and making emitter and reflector heights adjustments easier. Given the breadth of the peak P2, optimal values for HE and HR may fall in the ranges: 0.57λ≤HE≤0.58λ, and 0.53λ≤HR≤0.54λ.
An alternative design is shown in
Experiments indicate that the position of the nozzle opening within the chamber outlet can influence the trajectory of the ejected droplet. In a series of experiments, a nozzle (d=1 mm) is placed in the center of the subWAVE (dh=2 mm) at a height 2 mm from the exit 114 and translated in a radial direction. The nozzle takes three radial positions: center (0 μm), 100 μm from the center, and 200 μm from the center. The maximum nozzle displacement is 500 μm, at which point the nozzle touches the wall of the SUBWAVE. For displacements above 300 μm, clogging is occasionally observed. Ejected droplets are filmed and the movies are later analyzed using a custom Matlab© code that extracts information such as the droplet diameter and position.
The data show, as expected from simulations, that the droplet's trajectory is altered by the acoustic field as the nozzle is moved away from the center of the chamber outlet. For example, if the nozzle is displaced to the right, the trajectory of the droplet is moved to the right. It is further noted that the angle of ejection increases as the nozzle gets closer to the wall. This corresponds very well to the simulations since vRMS increases closer to the wall. It is interesting that the angle increases with the voltage up to 100 V but decreases at 150 V. At 150 V, the droplet's speed becomes large enough to counterbalance the effects of vRMS and the droplet has a more vertical trajectory.
Ideally, each droplet has the same exit angle and, if the substrate is moved straight, the printed droplets form a perfect straight line. However, the exit angle of successive droplets is not necessarily constant. In some cases, it may be advantageous to have as little exit angle variation as possible, in other words, to reduce the variance of the exit angle.
Displacement of the nozzle (and thus the nozzle opening) within the chamber outlet may be a very powerful tool to control the trajectory of the droplet. Using a micrometric stage for the nozzle displacement, it may be possible to precisely choose the exit angle and therefore the impact location.
The experimental set-up includes a sound source, an acoustic chamber and a fluid (ink) dispensing system.
Sound system: A magnetostrictive transducer (Etrema C18A) excites the resonant mode of an emitter (designed in-house). The resonance frequency of the system is 26.460 kHz. The transducer is driven by a sinusoidal signal at the resonance frequency of the system of 26.460 kHz and amplified to a maximum value of 115 V (Peavy CS4080).
Acoustic chamber: The acoustophoretic printing apparatus was designed and manufactured in-house with multiple acrylic parts. To allow for easy nozzle insertion, the acoustic chamber is rectangular, measuring 15 mm×65 mm×7.5 mm. The emitter is at one end and the chamber outlet is at the other end. The subwavelength chamber outlet takes the form of a cylindrical bore of 2 mm in diameter and 5.5 mm in length or height.
Fluid dispensing system: Experiments were performed with two positive displacement systems, including a syringe pump (Harvard apparatus) and a Nordson EDF2800 Ultra. Both systems utilize a Luer-lock connection to the nozzle. Tapered glass nozzles are manufactured in-house with a pipette puller (Sutter P-1000) and connected to a Luer-lock connector with epoxy glue. The nozzle tips are treated with a hydrophobic coating to reduce wetting.
Numerical Model
An axisymmetric linear acoustic model was implemented with an FEM solver to calculate the acoustic field inside the subWAVE. The acoustic force was calculated with both the Gor'kov potential model and the surface integral of the radiation pressure on the sphere.
Although the present invention has been described in considerable detail with reference to certain embodiments thereof, other embodiments are possible without departing from the present invention. The spirit and scope of the appended claims should not be limited, therefore, to the description of the preferred embodiments contained herein. All embodiments that come within the meaning of the claims, either literally or by equivalence, are intended to be embraced therein.
Furthermore, the advantages described above are not necessarily the only advantages of the invention, and it is not necessarily expected that all of the described advantages will be achieved with every embodiment of the invention.
The present patent document is the national stage of International Patent Application No. PCT/US2017/043539, which was filed on Jul. 24, 2017, and which claims the benefit of priority under 35 U.S.C. § 119(e) to U.S. Provisional Patent Application Ser. No. 62/367,318, which was filed on Jul. 27, 2016. Both of the aforementioned patent applications are hereby incorporated by reference in their entirety.
This invention was made with government support under contract number DMR-1420570 awarded by the National Science Foundation. The government has certain rights in the invention.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US2017/043539 | 7/24/2017 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2018/022513 | 2/1/2018 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5880759 | Silverbrook | Mar 1999 | A |
6003388 | Oeftering | Dec 1999 | A |
6422690 | Harvey | Jul 2002 | B1 |
7354141 | Elison et al. | Apr 2008 | B2 |
9878536 | Foresti et al. | Jan 2018 | B2 |
20060144871 | Van Tuyl et al. | Jul 2006 | A1 |
20060209129 | Onozawa | Sep 2006 | A1 |
20070085867 | Ishikawa | Apr 2007 | A1 |
20070231425 | Ream | Oct 2007 | A1 |
20090115820 | Nomura et al. | May 2009 | A1 |
20140097267 | Shitara | Apr 2014 | A1 |
20150037445 | Murphy | Feb 2015 | A1 |
20150118692 | Johnson | Apr 2015 | A1 |
20160367358 | Tran | Dec 2016 | A1 |
20170028721 | Barbet | Feb 2017 | A1 |
Number | Date | Country |
---|---|---|
WO 2014029505 | Feb 2014 | WO |
WO 2015110600 | Jul 2015 | WO |
Entry |
---|
Extended European Search Report, issued in EP Application No. 17835062.5, dated Feb. 20, 2020, pp. 1-10, European Patent Office, Munich, Germany. |
First Office Action with English translation, issued in CN Application No. 201780059622.3, dated Mar. 13, 2020, pp. 1-16, China Intellectual Property Administration, Beijing, CN. |
International Search Report and Written Opinion for International PCT No. PCTUS/2017/43539, dated Nov. 24, 2017, pp. 1-10. |
S. L. N. Ford, “Additive Manufacturing Technology: Potential Implications for U.S. Manufacturing Competitiveness,” Journal of International Commerce and Economics, Sep. 2014, pp. 1-35. |
J. Steele, “The Next Industrial Revolution: Functional Printing,” Printing News, Apr. 1, 2014, pp. 1-5. |
G. D. Martin and I. M. Hutchings, “Fundamentals of Ink Jet Technology,” in Inkjet Technology for Digital Fabrication, First Edition, John Wiley & Sons (2013) pp. 21-44. |
P.K. Kundu, I. M. Cohen and D. R. Dowling, “Conservation Laws,” in Fluid Mechanics, Elsevier, Inc. (2012) pp. 95-169. |
N. Bjelobrk et al., “Contactless transport of acoustically levitated particles,” Applied Physics Letters, 97 (2010) pp. 161904-1-161904-3. |
V. Vandaele et al., “Non-contact handling in microassembly: Acoustical levitation,” Precision Engineering, 29 (2006) pp. 491-505. |
E. H. Brandt, “Levitation in Physics,” Science, 243 (1989) pp. 349-355. |
H. Azhari, “Waves—A General Description,” in Basics of Biomedical Ultrasound for Engineers, John Wiley & Sons, Inc. (2010) pp. 9-33. |
L. V. King, “On the Acoustic Radiation of Pressure on Spheres,” Proceeding of the Royal Society of London, 147 (1934) p. 212. |
D. Foresti et al., “Contactless transport of matter in the first five resonance modes of a line-focused acoustic manipulator,” J. Acoust. Soc. Am., 131, 2 (2012) pp. 1029-1038. |
J. Christensen et al., “Theory of Resonant Acoustic Transmission through Subwavelength Apertures,” Physical Review Letters, 101 (2008) pp. 014301-1-014301-4. |
B. Hou, “Tuning Fabry-Perot resonances via diffraction evanescent waves,” Physical Review B, 76 (2007) pp. 054303-1-054303-054303-6. |
J. Renner et al., “Reproducibility of DoD Inkjet Printing Systems,” 38th International Research Conference, Advances in Printing and Media Technology, Budapest, 2011, pp. 1-8. |
D. Foresti et al., “Investigation of a line-focused acoustic levitation for contactless transport of particles,” Journal of Applied Physics, 109 (2011) pp. 0935503-1-0935503-11. |
S. Zhao and J. Wallaschek, “A standing wave acoustic levitation system for large planar objects,” Arch. Appl. Mech, vol. 81, 2011, pp. 123-139. |
D. Foresti and D. Poulikakos, “Acoustophoretic contactless elevation, orbital transport and spinning of matter in air,” Physical Review Letters, 112 (2014) pp. 024301-1-024301-5. |
S. Baer, “Analysis of the particle stability in a new designed ultrasonic levitation device,” Review of Scientific Instruments, 82 (2011) pp. 105111-1-105111-7. |
A. L. Yarin et al., “On the acoustic levitation of droplets,” Journal of Fluid Mechanics, 356 (1998) pp. 65-91. |
Y. Wu, “Development of Free Adjustable Function Generator for Drop-on-Demand Droplets Generation,” in Advances in Intelligent and Soft Computing, 160, Springer-Verlag (2012) pp. 477-481. |
M. Vaezi et al., “A review on 3D micro-additive manufacturing technologies,” Int. Journal of Adv. Manuf. Technol., 67 (2012) pp. 1721-1754. |
Y. Kim et al., “Design and Fabrication of Electrostatic Inkjet Head using Silicon Micromachining Technology,” Journal of Semiconductor Technology and Science, 8 (2008) pp. 121-127. |
S. Lee et al., “Electrostatic droplet formation and ejection of colloid,” Micro-Nanomechatronics and Human Science, (2004) pp. 1-6. |
M. Colina et al., “Laser-induced forward transfer of liquids: Study of the droplet ejection process,” Journal of Applied Physics, 99 (2006) pp. 084909-1-084909-7. |
P. Galliker et al., “Direct printing of nanostructures by electrostatic autofocussing of ink nanodroplets,” Nature Communications 3, 890 (2012) pp. 1-9. |
Number | Date | Country | |
---|---|---|---|
20190160813 A1 | May 2019 | US |
Number | Date | Country | |
---|---|---|---|
62367318 | Jul 2016 | US |