Centrifuge Explained

A centrifuge is a device that uses centrifugal force to subject a specimen to a specified constant force, for example to separate various components of a fluid. This is achieved by spinning the fluid at high speed within a container, thereby separating fluids of different densities (e.g. cream from milk) or liquids from solids. It works by causing denser substances and particles to move outward in the radial direction. At the same time, objects that are less dense are displaced and moved to the centre. In a laboratory centrifuge that uses sample tubes, the radial acceleration causes denser particles to settle to the bottom of the tube, while low-density substances rise to the top.[1] A centrifuge can be a very effective filter that separates contaminants from the main body of fluid.

Industrial scale centrifuges are commonly used in manufacturing and waste processing to sediment suspended solids, or to separate immiscible liquids. An example is the cream separator found in dairies. Very high speed centrifuges and ultracentrifuges able to provide very high accelerations can separate fine particles down to the nano-scale, and molecules of different masses. Large centrifuges are used to simulate high gravity or acceleration environments (for example, high-G training for test pilots). Medium-sized centrifuges are used in washing machines and at some swimming pools to draw water out of fabrics. Gas centrifuges are used for isotope separation, such as to enrich nuclear fuel for fissile isotopes.

History

English military engineer Benjamin Robins (1707–1751) invented a whirling arm apparatus to determine drag. In 1864, Antonin Prandtl proposed the idea of a dairy centrifuge to separate cream from milk.[2] The idea was subsequently put into practice by his brother, Alexander Prandtl, who made improvements to his brother's design, and exhibited a working butterfat extraction machine in 1875.[3]

Types

A centrifuge machine can be described as a machine with a rapidly rotating container that applies centrifugal force to its contents. There are multiple types of centrifuge, which can be classified by intended use or by rotor design:

Types by rotor design:[4] [5] [6] [7]

Types by intended use:

Industrial centrifuges may otherwise be classified according to the type of separation of the high density fraction from the low density one.

Generally, there are two types of centrifuges: the filtration and sedimentation centrifuges. For the filtration or the so-called screen centrifuge the drum is perforated and is inserted with a filter, for example a filter cloth, wire mesh or lot screen. The suspension flows through the filter and the drum with the perforated wall from the inside to the outside. In this way the solid material is restrained and can be removed. The kind of removing depends on the type of centrifuge, for example manually or periodically. Common types are:

In the centrifuges the drum is a solid wall (not perforated). This type of centrifuge is used for the purification of a suspension. For the acceleration of the natural deposition process of suspension the centrifuges use centrifugal force. With so-called overflow centrifuges the suspension is drained off and the liquid is added constantly. Common types are:[8]

Though most modern centrifuges are electrically powered, a hand-powered variant inspired by the whirligig has been developed for medical applications in developing countries.[9]

Many designs have been shared for free and open-source centrifuges that can be digitally manufactured. The open-source hardware designs for hand-powered centrifuge for larger volumes of fluids with a radial velocity of over 1750 rpm and over 50 N of relative centrifugal force can be completely 3-D printed for about $25.[10] Other open hardware designs use custom 3-D printed fixtures with inexpensive electric motors to make low-cost centrifuges (e.g. the Dremelfuge that uses a Dremel power tool) or CNC cut out OpenFuge.[11] [12] [13] [14]

Uses

Laboratory separations

See main article: Laboratory centrifuge. A wide variety of laboratory-scale centrifuges are used in chemistry, biology, biochemistry and clinical medicine for isolating and separating suspensions and immiscible liquids. They vary widely in speed, capacity, temperature control, and other characteristics. Laboratory centrifuges often can accept a range of different fixed-angle and swinging bucket rotors able to carry different numbers of centrifuge tubes and rated for specific maximum speeds. Controls vary from simple electrical timers to programmable models able to control acceleration and deceleration rates, running speeds, and temperature regimes. Ultracentrifuges spin the rotors under vacuum, eliminating air resistance and enabling exact temperature control. Zonal rotors and continuous flow systems are capable of handing bulk and larger sample volumes, respectively, in a laboratory-scale instrument.

An application in laboratories is blood separation. Blood separates into cells and proteins (RBC, WBC, platelets, etc.) and serum. DNA preparation is another common application for pharmacogenetics and clinical diagnosis. DNA samples are purified and the DNA is prepped for separation by adding buffers and then centrifuging it for a certain amount of time. The blood waste is then removed and another buffer is added and spun inside the centrifuge again. Once the blood waste is removed and another buffer is added the pellet can be suspended and cooled. Proteins can then be removed and the entire thing can be centrifuged again and the DNA can be isolated completely. Specialized cytocentrifuges are used in medical and biological laboratories to concentrate cells for microscopic examination.[15]

Isotope separation

See main article: Gas centrifuge. Other centrifuges, the first being the Zippe-type centrifuge, separate isotopes,[16] and these kinds of centrifuges are in use in nuclear power and nuclear weapon programs.

Aeronautics and astronautics

See main article: High-g training. Human centrifuges are exceptionally large centrifuges that test the reactions and tolerance of pilots and astronauts to acceleration above those experienced in the Earth's gravity.

The first centrifuges used for human research were used by Erasmus Darwin, the grandfather of Charles Darwin. The first large-scale human centrifuge designed for aeronautical training was created in Germany in 1933.[17]

The US Air Force at Brooks City Base, Texas, operates a human centrifuge while awaiting completion of the new human centrifuge in construction at Wright-Patterson AFB, Ohio. The centrifuge at Brooks City Base is operated by the United States Air Force School of Aerospace Medicine for the purpose of training and evaluating prospective fighter pilots for high-g flight in Air Force fighter aircraft.[18]

The use of large centrifuges to simulate a feeling of gravity has been proposed for future long-duration space missions. Exposure to this simulated gravity would prevent or reduce the bone decalcification and muscle atrophy that affect individuals exposed to long periods of freefall.[19]

Non-Human centrifuge

At the European Space Agency (ESA) technology center ESTEC (in Noordwijk, the Netherlands), an 8m (26feet) diameter centrifuge is used to expose samples in fields of life sciences as well as physical sciences. This Large Diameter Centrifuge (LDC)[20] began operation in 2007. Samples can be exposed to a maximum of 20 times Earth's gravity. With its four arms and six freely swinging out gondolas it is possible to expose samples with different g-levels at the same time. Gondolas can be fixed at eight different positions. Depending on their locations one could e.g. run an experiment at 5 and 10g in the same run. Each gondola can hold an experiment of a maximum . Experiments performed in this facility ranged from zebra fish, metal alloys, plasma,[21] cells,[22] liquids, Planaria,[23] Drosophila[24] or plants.

Industrial centrifugal separator

Industrial centrifugal separator is a coolant filtration system for separating particles from liquid like, grinding machining coolant. It is usually used for non-ferrous particles separation such as, silicon, glass, ceramic, and graphite etc. The filtering process does not require any consumption parts like filter bags, which saves the earth from harm.[25] [26]

Geotechnical centrifuge modeling

Geotechnical centrifuge modeling is used for physical testing of models involving soils. Centrifuge acceleration is applied to scale models to scale the gravitational acceleration and enable prototype scale stresses to be obtained in scale models. Problems such as building and bridge foundations, earth dams, tunnels, and slope stability, including effects such as blast loading and earthquake shaking.[27]

Synthesis of materials

High gravity conditions generated by centrifuge are applied in the chemical industry, casting, and material synthesis.[28] [29] [30] [31] The convection and mass transfer are greatly affected by the gravitational condition. Researchers reported that the high-gravity level can effectively affect the phase composition and morphology of the products.[28]

Commercial applications

Mathematical description

\omega

, and the acceleration relative to "g" is traditionally named "relative centrifugal force" (RCF). The acceleration is measured in multiples of "g" (or × "g"), the standard acceleration due to gravity at the Earth's surface, a dimensionless quantity given by the expression:

RCF=

r\omega2
g

where

styleg

is earth's gravitational acceleration,

styler

is the rotational radius,

\omega

is the angular velocity in radians per unit time

This relationship may be written as

RCF=

-3
10rmm
\left(2\piNRPM
60
\right)2
g

or

RCF=1.118(2) x 10-6rmm

2
N
RPM

where

stylermm

is the rotational radius measured in millimeters (mm), and

styleNRPM

is rotational speed measured in revolutions per minute (RPM).

To avoid having to perform a mathematical calculation every time, one can find nomograms for converting RCF to rpm for a rotor of a given radius. A ruler or other straight edge lined up with the radius on one scale, and the desired RCF on another scale, will point at the correct rpm on the third scale.[32] Based on automatic rotor recognition, modern centrifuges have a button for automatic conversion from RCF to rpm and vice versa.

See also

Further reading

External links

Notes and References

  1. Book: Mikkelsen . Susan R. . Centrifugation Methods . Bioanalytical Chemistry . Cortón . Eduardo . 2004-02-20 . John Wiley & Sons, Inc. . 978-0-471-54447-0 . Hoboken, NJ, US . 10.1002/0471623628.ch13.
  2. Web site: Amanda . 2022-06-10 . History of the Centrifuge . 2024-05-10 . The Lab World Group . en-US.
  3. Book: Vogel-Prandtl, Johanna . Ludwig Prandtl: A Biographical Sketch, Remembrances and Documents . V. Vasanta Ram . The International Centre for Theoretical Physics Trieste, Italy . August 14, 2004 . 10–11 . live . 2017-10-25 . https://web.archive.org/web/20171025143117/http://users.ictp.it/~krs/other/Prandtl_Book.pdf . 1904.
  4. Web site: Basics of Centrifugation . Cole-Parmer . 11 March 2012 . live . https://web.archive.org/web/20120224093736/http://www.coleparmer.com/TechLibraryArticle/30 . 24 February 2012.
  5. Web site: Plasmid DNA Separation: Fixed-Angle and Vertical Rotors in the Thermo Scientific Sorvall Discovery™ M120 & M150 Microultracentrifuges . Thermo Fisher . 2012-03-11 . 2012-02-24 . https://web.archive.org/web/20120224020710/http://www.thermo.com/eThermo/CMA/PDFs/Various/File_6810.pdf . dead.
  6. Web site: Centrifuges. 2012-03-11 . dead . 2014-05-13 . https://web.archive.org/web/20140513185937/http://uqu.edu.sa/files2/tiny_mce/plugins/filemanager/files/4250119/lectures/1._instr.pdf .
  7. Web site: Heidcamp . William H. . Appendix F . Cell Biology Laboratory Manual. Gustavus Adolphus College. 11 March 2012. dead . 2 March 2012. https://web.archive.org/web/20120302021430/http://homepages.gac.edu/~cellab/appds/appd-f.html.
  8. Web site: Centrifuges . Centrimax . 2016-11-09. 2016-11-09. https://web.archive.org/web/20161109224117/http://www.centrimax.com/centrifuges.html. live.
  9. . 1 . 0009 . M. Saad Bhamla . Brandon Benson . Chew Chai . Georgios Katsikis . Aanchal Johri . Manu Prakash . Hand-powered ultralow-cost paper centrifuge . 10 January 2017 . 10.1038/s41551-016-0009 . 16459214.
  10. Sule . Salil S. . Petsiuk . Aliaksei L. . Pearce . Joshua M. . 2019 . Open Source Completely 3-D Printable Centrifuge . Instruments . 3 . 2 . 30 . 10.3390/instruments3020030 . free.
  11. Web site: OpenFuge . www.instructables.com . 2019-10-27 . 2019-10-27 . https://web.archive.org/web/20191027095149/https://www.instructables.com/id/OpenFuge/ . live.
  12. Pearce . Joshua M. . 2012-09-14 . Building Research Equipment with Free, Open-Source Hardware . Science . 337 . 6100 . 1303–1304 . 10.1126/science.1228183 . 22984059 . 2012Sci...337.1303P . 44722829 . 0036-8075.
  13. Sleator . Roy D. . September 1, 2016 . DIY Biology – Hacking Goes Viral! . Science Progress . 99 . 3 . 278–281 . 28742489 . 3979794 . 10.3184/003685016X14684989326984 . 10365417 . free . 0036-8504.
  14. Meyer . Morgan . 2012-06-25 . Build your own lab: Do-it-yourself biology and the rise of citizen biotech-economies . Journal of Peer Production . 2 . online . 4 . live . 2019-10-27 . 2019-10-27 . https://web.archive.org/web/20191027095911/https://hal-mines-paristech.archives-ouvertes.fr/hal-00710829.
  15. Stokes . Barry O. . 2004 . Principles of Cytocentrifugation . Laboratory Medicine . 35 . 7 . 434–437 . 0007-5027 . 10.1309/FTT59GWKDWH69FB0 . free.
  16. Book: Iran's Weapons of Mass Destruction: The Real and Potential Threat . Cordesman. Anthony H.. Al-Rodhan . Khalid R.. 2006 . CSIS . 9780892064854 . 2018-03-25.
  17. Web site: Meeker . Larry J. . Human Centrifuges in Research and Training . https://web.archive.org/web/20160303225046/http://www.dtic.mil/dtic/tr/fulltext/u2/a236267.pdf . 2016-03-03.
  18. Web site: The Pull of HyperGravity – A NASA researcher is studying the strange effects of artificial gravity on humans. . NASA . 11 March 2012 . 16 March 2012 . https://web.archive.org/web/20120316183032/http://science.nasa.gov/science-news/science-at-nasa/2003/07feb_stronggravity/ . live.
  19. News: Hsu . Jeremy . New Artificial Gravity Tests in Space Could Help Astronauts . Space.com . 11 March 2012 . 7 March 2012 . https://web.archive.org/web/20120307065844/http://www.space.com/8384-artificial-gravity-tests-space-astronauts.html . live.
  20. van Loon . Jack J.W.A. . THE LARGE DIAMETER CENTRIFUGE, LDC, FOR LIFE AND PHYSICAL SCIENCES AND TECHNOLOGY . Krausse . Jutta . Cunha . Humberto . Goncalves . Joao . Almeida . Hugo . Schiller . Peter . June 2008 . "Life in Space for Life on Earth": Proceedings of the Symposium 22–27 June 2008, Angers, France . 553 . 92 . European Space Agency . 978-92-9221-227-8 . Ouwehand . L. . 2008ESASP.663E..92V.
  21. Šperka . Jiří . Souček . Pavel . Loon . Jack J. W. A. Van . Dowson . Alan . Schwarz . Christian . Krause . Jutta . Kroesen . Gerrit . Kudrle. Vít . 2013-12-01 . Hypergravity effects on glide arc plasma . The European Physical Journal D . 67 . 12 . 261 . 10.1140/epjd/e2013-40408-7 . 1434-6060 . 54539341 . 2013EPJD...67..261S . 2018-12-26 . 2021-03-08 . https://web.archive.org/web/20210308144821/https://is.muni.cz/repo/1137458 . live.
  22. Szulcek . Robert . Bezu . Jan van . Boonstra . Johannes . Loon . Jack J. W. A. van . Amerongen . Geerten P. van Nieuw. 2015-12-04 . Transient Intervals of Hyper-Gravity Enhance Endothelial Barrier Integrity: Impact of Mechanical and Gravitational Forces Measured Electrically . PLOS ONE . 10 . 12 . e0144269 . 10.1371/journal.pone.0144269 . 1932-6203 . 4670102 . 26637177 . 2015PLoSO..1044269S . free.
  23. Adell . Teresa . Saló . Emili . Loon . Jack J. W. A. van . Auletta . Gennaro . 2014-09-17 . Planarians Sense Simulated Microgravity and Hypergravity . BioMed Research International . 2014 . 679672 . 10.1155/2014/679672 . 2314-6133 . 4182696 . 25309918 . free.
  24. Serrano . Paloma . van Loon . Jack J. W. A. . Medina . F. Javier . Herranz . Raúl . 27 November 2012 . Relation Between Motility, Accelerated Aging and Gene Expression in Selected Drosophila Strains under Hypergravity Conditions . Microgravity Science and Technology . 25 . 1 . 67–72 . 10.1007/s12217-012-9334-5 . 10261/99914 . 2121465 . 0938-0108. free.
  25. Web site: What is an Industrial Centrifuge? An industrial centrifuge is a machine used for fluid/particle sep. KYTE. 21 September 2017. 21 September 2017. https://web.archive.org/web/20170921095954/http://kytecentrifuge.com/centrifuge/. live.
  26. Web site: Chip Removal Centrifugal Machine. Chinminn. 7 January 2020. 12 August 2020. https://web.archive.org/web/20200812014954/https://www.chinminn.com/en/product/centrifugal-separator/automatic-chip-removal-centrifugal-machine. live.
  27. Book: Physical Modelling in Geotechnics: proceedings of the Sixth International Conference on Physical Modelling in Geotechnics . C. W. W. Ng . Y. H. Wang . L. M. Zhang . 2006 . 135 . 978-0-415-41586-6 . Taylor & Francis . 2016-11-02 . 2021-03-08 . https://web.archive.org/web/20210308042550/https://books.google.com/books?id=mzQlFBqJC1wC&pg=RA1-PA186 . live.
  28. Yin . Xi . Chen pramodn . Zhou . Heping . Ning . Xiaoshan . Combustion Synthesis of Ti3SiC2/TiC Composites from Elemental Powders under High-Gravity Conditions . Journal of the American Ceramic Society . August 2010 . 93 . 8 . 2182–2187 . 10.1111/j.1551-2916.2010.03714.x.
  29. Mesquita . R.A. . Leiva . D.R. . Yavari . A.R. . Botta Filho . W.J. . Microstructures and mechanical properties of bulk AlFeNd(Cu,Si) alloys obtained through centrifugal force casting . Materials Science and Engineering: A. April 2007 . 452–453 . 161–169 . 10.1016/j.msea.2006.10.082.
  30. Chen . Jian-Feng . Wang . Yu-Hong . Guo . Fen . Wang . Xin-Ming . Zheng . Chong . Synthesis of Nanoparticles with Novel Technology: High-Gravity Reactive Precipitation . Industrial & Engineering Chemistry Research . April 2000 . 39 . 4 . 948–954 . 10.1021/ie990549a.
  31. Abe . Yoshiyuki . Maizza . Giovanni . Bellingeri . Stefano . Ishizuka . Masao . Nagasaka . Yuji . Suzuki . Tetsuya . Diamond synthesis by high-gravity d.c. plasma cvd (hgcvd) with active control of the substrate temperature . Acta Astronautica . January 2001 . 48 . 2–3 . 121–127 . 10.1016/S0094-5765(00)00149-1 . 2001AcAau..48..121A.
  32. Web site: Nomogram for converting maximum relative centrifugal force (RCF, i.e., g-force) to RPM . https://web.archive.org/web/20131209161103/http://aquaticpath.umd.edu/nomogram.html . December 9, 2013 . University of Maryland Aquatic Pathobiology Center.