2016
DOI: 10.1007/s12206-016-0527-5
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Thermal analysis of wirelessly powered thermo-pneumatic micropump based on planar LC circuit

Abstract: This paper studies the thermal behavior of a wireless powered micropump operated using thermo-pneumatic actuation. Numerical analysis was performed to investigate the temporal conduction of the planar inductor-capacitor (LC) wireless heater and the heating chamber. The result shows that the temperature at the heating chamber reaches steady state temperature of 46.7°C within 40 seconds. The finding was further verified with experimental works through the fabrication of the planar LC heater (RF sensitive actuato… Show more

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Cited by 32 publications
(10 citation statements)
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“…This intermittent volume delivers a recurrent impetus for fluid flows, which creates a considerably large induced pressure and a membrane displacement [128,131]. To initiate the transfer of heat from the human body to the micropump, several mechanisms have been implemented, such as body heat-powered or fermentation-powered operations [132,133].…”
Section: Thermo-pneumatic Micropumpsmentioning
confidence: 99%
“…This intermittent volume delivers a recurrent impetus for fluid flows, which creates a considerably large induced pressure and a membrane displacement [128,131]. To initiate the transfer of heat from the human body to the micropump, several mechanisms have been implemented, such as body heat-powered or fermentation-powered operations [132,133].…”
Section: Thermo-pneumatic Micropumpsmentioning
confidence: 99%
“…To overcome this limit, many other methods have been developed to manipulate and control the microscale flow, primarily utilizing discontinuous surface stress on an active surface. [15] These methods can be generated by thermal gradient, [16,17] magnetohydrodynamics, [18,19] electrohydrodynamic, [20,21] or by surface modification. [22] In microfluidics, two types of electrophoretic micropumps are commonly used: direct current (DC) electroosmotic pumps and alternating current (AC) electroosmotic pumps.…”
Section: Introductionmentioning
confidence: 99%
“…To overcome this limit, many other methods have been developed to manipulate and control the microscale flow, primarily utilizing discontinuous surface stress on an active surface. [ 15 ] These methods can be generated by thermal gradient, [ 16,17 ] magnetohydrodynamics, [ 18,19 ] electrohydrodynamic, [ 20,21 ] or by surface modification. [ 22 ]…”
Section: Introductionmentioning
confidence: 99%
“…Internet connection has fundamentally changed the arrangements for monitoring and control and the use of open or public standards and personal computer systems (PCs, tablets, smart phones) bring significant benefits to their users and producers [7]. This concept can be further extended to be integrated into various wearable energy harvesting devices [8] and implantable wireless biomedical applications, such as wireless micropumps, micromixers, and microvalves [9][10][11].…”
Section: Introductionmentioning
confidence: 99%