Micro-Flow Control and Micropump by Applying Electric Fields through a Porous Membrane

Hasegawa, Tomiichi; Toga, Shinji; Morita, Makoto; Narumi, Takatsune; Uesaka, Nobuhiro

doi:10.1299/jsmeb.47.557

Cited by 4 publications

(3 citation statements)

References 5 publications

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“…Certain undesirable chemical changes can be produced by the electrolyte or gases trapped inside, but these can be driven out of the structure just by heating the preform at a temperature of about 200-300 C. The transport of ions inside the porous structure depends on a number of factors such as their concentration in the electrolyte, ionic mobility and crystal radius and diffusion coefficient (Hasegawa, 2004). …”

Section: Need For This Researchmentioning

confidence: 99%

Electrochemical deposition of metal ions in porous laser sintered inter‐metallic and ceramic preforms

Goel

Bourell

2011

Rapid Prototyping Journal

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PurposeThe purpose of this paper is to establish a scientific understanding for electrochemical infiltration of laser sintered (LS) preforms.Design/methodology/approachElectrochemical deposition techniques were modified to induce infiltration of nickel ions inside porous LS structures with deposition on pore walls.FindingsThis novel process is feasible and has the potential to produce fully dense parts. Both conductive and non‐conductive preforms can be infiltrated by this method.Research limitations/implicationsRemoval of trapped fluids and gases inside the porous structure is one of the major challenges in the described electrochemical infiltration process.Practical implicationsThis work enables low‐cost production of structural parts. It expands the application base for additive manufacturing, especially laser sintering technology.Social implicationsThe novel process carried out in this research is energy efficient when compared to state‐of‐the‐art vacuum‐melt infiltration.Originality/valueThe proposed process is a novel method for facilitating room‐temperature infiltration of porous LS preforms.

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Section: Need For This Researchmentioning

confidence: 99%

Electrochemical deposition of metal ions in porous laser sintered inter‐metallic and ceramic preforms

Goel

Bourell

2011

Rapid Prototyping Journal

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“…The differential pressure produced between the channels is the highest among the currently available micropumps, in the range of 0.1-1 atm. With the application of porous frit or nanoporous structures for the channel wall, or packing of nanoparticles in the channel, EO pumps with differential pressure up to 20 atm have been developed [25][26][27], which is suitable for high volumetric pumping. The voltage used for EO micropumps is in the range of a few tens of volts and increases up to 1.5 kV for those with high differential pressure.…”

Section: Electrokinetic Microfluidicsmentioning

confidence: 99%

Moving-part-free microfluidic systems for lab-on-a-chip

Luo¹,

Fu²,

Li³

et al. 2009

J. Micromech. Microeng.

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Microfluidic systems are part of an emerging technology which deals with minute amount of liquids (biological samples and reagents) on a small scale. They are fast, compact and can be made into a highly integrated system to deliver sample purification, separation, reaction, immobilization, labelling, detection, etc, and thus are promising for applications such as lab-on-a-chip and handheld healthcare devices. Miniaturized micropumps typically consist of a moving-part component, such as a membrane structure, to deliver liquids, and they are unreliable, complicated in structure and difficult to be integrated with other control electronics circuits. The trend of new-generation micropumps is moving-part-free micropumps operated by advanced techniques, such as electrokinetic force, surface tension/energy, acoustic waves, etc. This paper reviews the development and advances of the relevant technologies, and introduces the electrowetting-on-dielectrics and acoustic wave-based microfluidics. The programmable electrowetting micropump has been realized to dispense and manipulate droplets in 2D with up to 1000 addressable electrodes and electronics built underneath. The acoustic wave-based microfluidics can be used not only for pumping, mixing and droplet generation but also for biosensors, suitable for single-mechanism-based lab-on-chips application.

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“…Various types of pumps have been designed and fabricated using different mechanisms, e.g., gas pump is actuated and controlled by gas 6,7 and piezoelectric transducer actuator pump utilizes electrical/ mechanical energy conversion. 8 There is also the electroosmosis pump 9 for pumping ionic solutions, e.g., NaCL and KCL. Here we present an application of the electrorheological ͑ER͒ fluid in the design and fabrication of a micropump, with programmable digital control.…”

mentioning

confidence: 99%

Electrorheological fluid-actuated microfluidic pump

Liu

Chen

Niu

et al. 2006

Applied Physics Letters

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The authors report the design and implementation of an electrorheological ͑ER͒ fluid-actuated microfluidic pump, with programmable digital control. Our microfluidic pump has a multilayered structure fabricated on polydimethylsiloxane by soft-lithographic technique. The ER microfluidic pump exhibits good performance at high pumping frequencies and uniform liquid flow characteristics. It can be easily integrated with other microfluidic components. The programmable control also gives the device flexibility in its operations.

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Micro-Flow Control and Micropump by Applying Electric Fields through a Porous Membrane

Cited by 4 publications

References 5 publications

Electrochemical deposition of metal ions in porous laser sintered inter‐metallic and ceramic preforms

Electrochemical deposition of metal ions in porous laser sintered inter‐metallic and ceramic preforms

Moving-part-free microfluidic systems for lab-on-a-chip

Electrorheological fluid-actuated microfluidic pump

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