Tesla valve

A Tesla valve, called by Tesla a valvular conduit, is a fixed-geometry passive check valve. It allows a fluid to flow preferentially in one direction, without moving parts. The device is named after Nikola Tesla, who was awarded U.S. Patent 1,329,559 in 1920 for its invention. The patent application describes the invention as follows:[1]

The interior of the conduit is provided with enlargements, recesses, projections, baffles, or buckets which, while offering virtually no resistance to the passage of the fluid in one direction, other than surface friction, constitute an almost impassable barrier to its flow in the opposite direction.

Cross-section of a Tesla valve, displaying its cavity design, from the original patent application.

Tesla illustrates this with the drawing, showing one possible construction with a series of eleven flow-control segments, although any other number of such segments could be used as desired to increase or decrease the flow regulation effect.

One computational fluid dynamics simulation of Tesla valves with two and four segments showed that the flow resistance in the blocking (or reverse) direction was about 15 and 40 times greater, respectively, than the unimpeded (or forward) direction.[2] This lends support to Tesla's patent assertion that in the valvular conduit in his diagram, a pressure ratio "approximating 200 can be obtained so that the device acts as a slightly leaking valve".[1]

The Tesla valve is used in microfluidic applications[3] and offers advantages such as scalability, durability, and ease of fabrication in a variety of materials.[4]

Diodicity

The valves are structures that have a higher pressure drop for the flow in one direction (reverse) than the other (forward). This difference in flow resistance causes a net directional flow rate in the forward direction in oscillating flows. The efficiency is often expressed in diodicity $Di$ , being the ratio of pressure drops for identical flow rates:[5]

Di=\left({\frac {\Delta p_{r}}{\Delta p_{f}}}\right)_{Q},

where $\Delta p_{r}$ is the reverse flow pressure drop, and $\Delta p_{f}$ the forward flow pressure drop for flow rate $Q$ .

References

"Patent #: US001329559". United States Patent and Trademark Office. Office of the Chief Communications Officer. Retrieved 2 January 2017.
"Tesla's Valvular Conduit - Fluid Power Journal". Fluid Power Journal. 2013-10-23. Archived from the original on 2017-01-13. Retrieved 2017-01-13.
Deng, Yongbo; Liu, Zhenyu; Zhang, Ping (28 Jan 2010). "Optimization of no-moving part fluidic resistance microvalves with low reynolds number". Micro Electro Mechanical Systems (MEMS), 2010 IEEE 23rd International Conference on: 67–70. doi:10.1109/MEMSYS.2010.5442565. ISBN 978-1-4244-5761-8.
Gamboa, Adrian R.; Morris, Christopher J.; Forster, Fred K. (2005). "Improvements in Fixed-Valve Micropump Performance Through Shape Optimization of Valves". Journal of Fluids Engineering. 127 (2): 339. doi:10.1115/1.1891151.
de Vries; Florea; Homburg; Frijns (2017). "Design and operation of a tesla-type valve for pulsating heat pipes". International Journal of Heat and Mass Transfer. 105: 1–11. doi:10.1016/j.ijheatmasstransfer.2016.09.062.

External links

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[Patent-1] "Patent #: US001329559". United States Patent and Trademark Office. Office of the Chief Communications Officer. Retrieved 2 January 2017.

[CFD-2] "Tesla's Valvular Conduit - Fluid Power Journal". Fluid Power Journal. 2013-10-23. Archived from the original on 2017-01-13. Retrieved 2017-01-13.

[microvalves-3] Deng, Yongbo; Liu, Zhenyu; Zhang, Ping (28 Jan 2010). "Optimization of no-moving part fluidic resistance microvalves with low reynolds number". Micro Electro Mechanical Systems (MEMS), 2010 IEEE 23rd International Conference on: 67–70. doi:10.1109/MEMSYS.2010.5442565. ISBN 978-1-4244-5761-8.

[Micropump-4] Gamboa, Adrian R.; Morris, Christopher J.; Forster, Fred K. (2005). "Improvements in Fixed-Valve Micropump Performance Through Shape Optimization of Valves". Journal of Fluids Engineering. 127 (2): 339. doi:10.1115/1.1891151.

[diodicity-5] Vries; Florea; Homburg; Frijns (2017). "Design and operation of a tesla-type valve for pulsating heat pipes". International Journal of Heat and Mass Transfer. 105: 1–11. doi:10.1016/j.ijheatmasstransfer.2016.09.062.

Nikola Tesla
Career and inventions	Patents Magnifying transmitter Plasma lamp plasma globe Polyphase system Alternating-current commutatorless induction motor Tesla Experimental Station Teleforce Telegeodynamics Tesla coil history Wireless power Resonant inductive coupling Radio control Tesla turbine Tesla's oscillator Tesla valve Three-phase electric power Wardenclyffe Tower Tesla Electric Light and Manufacturing
Writings	The Inventions, Researches, and Writings of Nikola Tesla Colorado Springs Notes, 1899–1900 "Fragments of Olympian Gossip" My Inventions: The Autobiography of Nikola Tesla
Other	War of the currents Westinghouse Electric World Wireless System In popular culture
Related	Nikola Tesla Museum Nikola Tesla Memorial Center Tesla Science Center at Wardenclyffe IEEE Nikola Tesla Award Tesla Satellite Award Belgrade Nikola Tesla Airport New Yorker Hotel The Secret of Nikola Tesla (1980 film) Tesla - Lightning in His Hand (2003 opera) The Prestige (2006 film) Tower to the People (2015 documentary) Tesla (2016 film) The Tesla World Light (2017 film) The Current War (2019 film) "Nikola Tesla's Night of Terror" (2020 TV episode) Tesla (2020 film) Tesla: Man Out of Time Wizard: The Life and Times of Nikola Tesla The Man Who Invented the Twentieth Century SI derived unit Lunar crater Asteroid

Tesla valve

Diodicity

See also

References

External links