Drops, Jets and High-Resolution 3D Printing: Fundamentals and Applications

Caulfield, Richard; Fang, Feihuang; Tiwari, Manish K.

doi:10.1007/978-981-10-7233-8_6

Cited by 3 publications

(3 citation statements)

References 88 publications

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“…1,2 The resultant wetting from the droplet−surface interactions is a central theme in many applications such as spray cooling, 3−5 spray coating, 6,7 spray combustion, 8 inkjet printing, 9 3Dprinting, 10,11 ceramics, 12 and metals. 13 The spreading behavior of droplets on dry surfaces is governed by a balance between the inertial, viscous, and surface tension forces. The droplet's spreading characteristics can have markedly different outcomes due to surface roughness and surface wettability through the contact angle it makes with the surface.…”

Section: ■ Introductionmentioning

confidence: 99%

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Effect of Surface Roughness on Hydrodynamic Characteristics of an Impinging Droplet

Singh

Hodgson

Sen³

et al. 2021

Langmuir

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The influence of surface roughness and impact energy on the hydrodynamic behavior of water droplets impinging upon dry and rigid surfaces of known roughness has been investigated experimentally. The influence of these two parameters on the droplet maximum spreading diameter, slip length during droplet recoil, dynamic contact angle, contact angle hysteresis, and apparent contact angle of droplets at rest has been determined. Based on the quantitative assessment, a correlation for the maximum spreading diameter in terms of the nondimensional parameter (We/Oh) and surface roughness ratio (R a/d o) was derived. We propose to use surface roughness “R a” rather than using the contact angle for correlation as contact angles cannot be known a priori, whereas surface roughness can be determined beforehand. The wetting state of a droplet depends on the combined influence of droplet impact energy and surface roughness. While increasing impact energy increases the spreading, higher surface roughness resists the droplet from spreading. Low impact energy and a smoother surface tend toward the Cassie–Baxter wetting state, whereas high impact energy and rough surfaces propel the droplet toward the Wenzel state of wetting.

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Section: ■ Introductionmentioning

confidence: 99%

“…The resultant wetting from the droplet–surface interactions is a central theme in many applications such as spray cooling, − spray coating, , spray combustion, inkjet printing, 3D-printing, , ceramics, and metals …”

Section: Introductionmentioning

confidence: 99%

Effect of Surface Roughness on Hydrodynamic Characteristics of an Impinging Droplet

Singh

Hodgson

Sen³

et al. 2021

Langmuir

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“…A previous study has demonstrated the use of custom-made nozzles with a microcapillary with minimum filament size down to 1 μm (with D c = 0.5–5 μm) . The decrease in D c causes a pronounced increase in pressure drop across the nozzle (Δ P ∼ 1/ D c 4 for Newtonian fluids) . The use of nozzles with small D c is therefore limited by the applicable pressure to the system.…”

Section: Resultsmentioning

confidence: 99%

Embedded Core–Shell 3D Printing (eCS3DP) with Low-Viscosity Polysiloxanes

Karyappa

Goh

Hashimoto

2022

ACS Appl. Mater. Interfaces

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Flexible core–shell 3D structures are essential for the development of soft sensors and actuators. Despite recent advancements in 3D printing, the fabrication of flexible 3D objects with internal architectures (such as channels and void spaces) remains challenging with liquid precursors due to the difficulty to maintain the printed structures. The difficulty of such fabrication is prominent especially when low-viscosity polysiloxane resins are used. This study presents a unique approach to applying direct ink writing (DIW) 3D printing in a three-phase system to overcome this limitation. We performed core–shell 3D printing using a low-viscosity commercial polysiloxane resin (Ecoflex 10) as shell inks combined with a coaxially extruded core liquid (Pluronic F127) in Bingham plastic microparticulate gels (ethanol gel). In the process termed embedded core–shell 3D printing (eCS3DP), we highlighted the dependence of the rheological characteristics of the three fluids on the stability of the printed core–shell filament. With the core liquid with a sufficiently high concentration of Pluronic F127 (30 w/w%; σy = 158.5 Pa), the interfacial instability between the shell liquid and core liquid was suppressed; the removal of the core liquid permitted the fabrication of perfusable channels. We identified the printing conditions to ensure lateral attachments of printed core–shell filaments. Interestingly, judicious selection of the rheological properties and flow rates of three phases allowed the formation of droplets consisting of core liquids distributed along the printed filaments. eCS3DP offers a simple route to fabricate 3D structures of a soft elastomeric matrix with embedded channels and should serve as a useful tool for DIW-based fabrication of flexible wearable devices and soft robotic components.

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